Function of Ubiquinone in Escherichia coli: a Mutant Strain Forming a Low Level of Ubiquinone

A ubiquinone-deficient mutant of Escherichia coli K-12 forming 20% of the normal amount of ubiquinone was compared with a normal strain. This lowered concentration of ubiquinone is still four times the concentration of cytochrome b(1). The mutant strain grew more slowly than the normal strain on a minimal medium with glucose as sole source of carbon and gave a lower aerobic growth yield than the normal strain. The reduced nicotinamide adenine dinucleotide (NADH) oxidase rate in membranes from the mutant strain was 40% of the oxidase rate in membranes from the normal strain, and the percentage reduction of cytochrome b(1) in the aerobic steady state, with NADH as substrate, was increased in membranes from the mutant strain. It is concluded that ubiquinone is required for maximum oxidase activity at the relatively high concentration (27 times that of cytochrome b(1)) found in normal cells. The results are discussed in relation to a scheme previously advanced for ubiquinone function in E. coli.     

Pathway for Ubiquinone Biosynthesis in Escherichia coli K-12: Gene-Enzyme Relationships and Intermediates

Seven ubiquinone-deficient mutants of Escherichia coli, each of which accumulates two phenolic precursors of ubiquinone, have been characterized, and the accumulated compounds have been identified. The mutants accumulate small quantities of 2-octaprenyl-6-methoxyphenol, which was isolated and characterized by nuclear magnetic resonance and mass spectrometry, and relatively large amounts of 2-octaprenylphenol, a compound previously identified from E. coli. They also accumulate small quantities of a compound identified as 2-(hydroxyoctaprenyl)phenol although the relevance of this compound to the biosynthesis of ubiquinone is not clear. The results of genetic analysis suggest that each of the mutants carries a mutation in a gene (designated ubiH) which is located at about min 56 on the E. coli chromosome and is co-transducible with the serA and lysB genes. Based on information obtained from this and previous studies with ubiquinone-deficient mutants, a pathway is proposed for ubiquinone biosynthesis in E. coli, and a summary of the known gene-enzyme relationships is given.     

The respiratory chain of a newly isolated Methylomonas Pl1.

1. Whole cells of Methylomonas Pl1 contained ubiquinone, identified as ubiquinone-8. No naphthaquinone was detected. Ubiquinone was located predominantly in the particulate fraction, which also contained most of the NADH oxidase activity. 2. Aerobic incubation of cells with formaldehyde or methanol resulted in about 20% reduction of ubiquinone, irrespective of the presence or absence of dinitrophenol. On inhibition of the respiration by cyanide, ubiquinone became partly reduced by endogenous substrates (15--25%), and a further reduction occurred only in the presence of formaldehyde (up to 60%). When endogenous substrates were completely exhausted, then 44 and 23% of ubiquinone was reduced by formaldehyde or methanol respectively. 3. The difference spectra at room and liquid-N2 temperatures revealed the presence of cytochrome b and two cytochromes c (c-552.5 and c-549) all tightly bound to the membrane. Cytochrome c-552.5 was also found in the soluble fraction. 4. Redox changes of cytochromes b and c, with methanol or formaldehyde as substrates, respond to the aerobic and anaerobic states of the cell and to KCN inhibition in a manner characteristic of the electron carriers of the respiratory chain. 5. The merging point for electron transport from NADH dehydrogenase and formaldehyde dehydrogenase is suggested to be at the level of ubiquinone.     

The interaction of quinone analogues with wild-type and ubiquinone-deficient yeast mitochondria

The interaction of the exogenous quinones, duroquinone (DQ) and the decyl analogue of ubiquinone (DB) with the mitochondrial respiratory chain was studied in both wild-type and a ubiquinone-deficient mutant of yeast. DQ can be reduced directly by NADH dehydrogenase, but cannot be reduced by succinate dehydrogenase in the absence of endogenous ubiquinone. The succinate-driven reduction of DQ can be stimulated by DB in a reaction inhibited 50% by antimycin and 70-80% by the combined use of antimycin and myxothiazol, suggesting that electron transfer occurs via the cytochrome b-c1 complex. Both DQ and DB can effectively mediate the reduction of cytochrome b by the primary dehydrogenases through center o, but their ability to mediate the reduction of cytochrome b through center i is negligible. Two reaction sites for ubiquinol seem to be present at center o: one is independent of endogenous Q6 with a high reaction rate and a high Km; the other is affected by endogenous Q6 and has a low reaction rate and a low Km. By contrast, only one ubiquinol reaction site was observed at center i, where DB appears to compete with endogenous Q6. DB can oxidize most of the pre-reduced cytochrome b, while DQ can oxidize only 50%. On the basis of these data, the possible binding patterns of DB on different Q-reaction sites and the requirement for ubiquinone in the continuous oxidation of DQH are discussed.     

Role of quinones in the branch of the Escherichia coli respiratory chain that terminates in cytochrome o.

The role of quinones in the cytochrome o branch of the Escherichia coli respiratory chain was investigated by using mutant strains lacking the cytochrome d terminal oxidase complex. The only cytochromes present were cytochrome b556 and the cytochrome o complex, consisting of cytochrome b555-b562. Mutant strains missing ubiquinone, menaquinone, or both were constructed in the cytochrome d-minus (cyd) background. The steady-state levels of cytochrome b reduction were examined and compared in these strains to assess the effects of the quinone deficiencies. The data clearly show that a ubiquinone deficiency results in a lower level of cytochrome b reduction in the steady state. The data are consistent with a simple model in which ubiquinone is placed on the dehydrogenase side of all the cytochromes in this branch of the respiratory chain. There is no evidence from these experiments for a role of quinones in the respiratory chain at any site besides this one.     

Role of ubiquinone in hydrogen-dependent electron transport in Rhizobium japonicum.

Direct evidence for the involvement of ubiquinone in H2 oxidation by Rhizobium japonicum was demonstrated; H2 reduced ca. 80% of the extractable ubiquinone. The inhibitor 2-n-heptyl-4-hydroxyquinoline-N-oxide blocked electron transport at a site between ubiquinone and the cytochromes. The results showed that no cytochrome component mediates electron flow from hydrogen to ubiquinone.     

Inhibition of electron transfer from ferrocytochrome b to ubiquinone, cytochrome c1 and duroquinone by antimycin.

The effect of antimycin on (i) the respiratory activity of the KCN-insensitive pathway of mitochondria of Neurospora grown on chloramphenicol (chloramphenicol-grown) with durohydroquinone and succinate or NADH as substrate, (ii) the electron transfer from the b-type cytochromes to ubiquinone with durohydroquinone as electron donor as well as (iii) the electron transfer from the b-type cytochromes to duroquinone with succinate as electron donor in chloramphenicol-grown Neurospora and beef heart submitochondrial particles was studied. All experiments were performed in the uncoupled state. 1. The respiratory chain of chloramphenicol-grown Neurospora mitochondria branches at ubiquinone into two pathways. Besides the cytochrome oxidase-dependent pathway, a KCN-insensitive branch equiped with a salicylhydroxamate-sensitive oxidase exists. Durohydroquinone, succinate or NADH are oxidized via both pathways. The durohydroquinone oxidation via the KCN-insensitive pathway is inhibited by antimycin, wheras the succinate or NADH oxidation is not. The titer for ful inhibition is one mol antimycin per mol cytochrome b-563 or cytochrome b-557. 2. The electron transfer from durohydroquinone to ubiquinone, which takes place in the KCN-inhibited state, does not occur in the antimycin-inhibited state. 3. The reduction of duroquinone by succinate in the presence of KCN is inhibited by antimycin. The titer for full inhibition is one mol antimycin per mol cytochrome b-566 or cytochrome b-562 for beef heart (or cytochrome b-563 or cytochrome b-557 for Neurospora). 4. When electron transfer from the b-type cytochromes to cytochrome C1, ubiquinone and duroquinone is inhibited by antimycin, the hemes of cytochrome b-566 and cytochrome b-562 (or cytochrome b-563 and cytochrome b-557) are in the reduced state. 5. The experimental results suggest that the two b-type cytochromes form a binary complex the electron transferring activity of which is inhibited by antimycin, the titer for full inhibition being one mol of antimycin per mol of complex. The electron transfer from the b-type cytochromes to ubiquinone is inhibited in a non-linear fashion.     

Pyridoxal phosphate-induced dissociation of the succinate: ubiquinone reductase

Treatment of the soluble ubiquinone-deficient succinate: ubiquinone reductase with pyridoxal phosphate results in the inhibition of the carboxin-sensitive ubiquinone-reductase activity of the enzyme. The inactivation is prevented by the soluble homolog of ubiquinone (Q2) but is insensitive to the dicarboxylates interacting with the substrate binding site of succinate dehydrogenase. The reactivity of the pyridoxal phosphate-inhibited enzyme with different electron acceptors suggests that the observed inhibition is due to the dissociation of succinate dehydrogenase from the enzyme complex. The soluble succinate dehydrogenase was recovered in the supernatant after treatment of the insoluble succinate: ubiquinone reductase with pyridoxal phosphate. The data obtained strongly suggest the participation of amino groups in the interaction between succinate dehydrogenase and the ubiquinone reactivity conferring peptide within the complex.     

Ubiquinone deficiency in an auxotroph of Escherichia coli requiring 4-hydroxybenzoic acid

1. Escherichia coli 156:53D2 synthesized ubiquinone only when the growth medium was supplemented with 4-hydroxybenzoate acid. 2. Little or no vitamin K(2) was formed by the mutant under the growth conditions employed, in contrast with wild-type strains. 3. In the mutant ubiquinone deficiency was correlated with low respiration and with low particulate NADH-oxidase and NADH-cytochrome b(1)-reductase activity. 4. Preincubation of ubiquinone-deficient particles with ubiquinone-30 largely restored the NADH-oxidase and NADH-cytochrome b(1)-reductase activities. 5. Various NADH-dye-linked reductases which may be associated with NADH dehydrogenase were not affected by the absence of ubiquinone. 6. The succinate-oxidase complex was less affected than the particulate NADH oxidase by ubiquinone deficiency. 7. A pathway for electrons in the NADH-oxidase complex of the auxotroph of E. coli is proposed and its relationship to the pathway in the wild-type strain is discussed.     

Comparison of a coq7 deletion mutant with other respiration-defective mutants in fission yeast

Among the steps in ubiquinone biosynthesis, that catalyzed by the product of the clk-1/coq7 gene has received considerable attention because of its relevance to life span in Caenorhabditis elegans. We analyzed the coq7 ortholog (denoted coq7) in Schizosaccharomyces pombe, to determine whether coq7 has specific roles that differ from those of other coq genes. We first confirmed that coq7 is necessary for the penultimate step in ubiquinone biosynthesis, from the observation that the deletion mutant accumulated the ubiquinone precursor demethoxyubiquinone-10 instead of ubiquinone-10. The coq7 mutant displayed phenotypes characteristic of other ubiquinone-deficient Sc. pombe mutants, namely, hypersensitivity to hydrogen peroxide, a requirement for antioxidants for growth on minimal medium, and an elevated production of sulfide. To compare these phenotypes with those of other respiration-deficient mutants, we constructed cytochrome c (cyc1) and coq3 deletion mutants. We also assessed accumulation of oxidative stress in various ubiquinone-deficient strains and in the cyc1 mutant by measuring mRNA levels of stress-inducible genes and the phosphorylation level of the Spc1 MAP kinase. Induction of ctt1, encoding catalase, and apt1, encoding a 25 kDa protein, but not that of gpx1, encoding glutathione peroxidase, was indistinguishable in four ubiquinone-deficient mutants, indicating that the oxidative stress response operates at similar levels in the tested strains. One new phenotype was observed, namely, loss of viability in stationary phase (chronological life span) in both the ubiquinone-deficient mutant and in the cyc1 mutant. Finally, Coq7 was found to localize in mitochondria, consistent with the possibility that ubiquinone biosynthesis occurs in mitochondria in yeasts. In summary, our results indicate that coq7 is required for ubiquinone biosynthesis and the coq7 mutant is not distinguishable from other ubiquinone-deficient mutants, except that its phenotypes are more pronounced than those of the cyc1 mutant.     

The respiratory chain of plant mitochondria. XV. Equilibration of cytochromes c549, b553, b557 and ubiquinone in mung bean mitochondria: Placement of cytochrome b557 and estimation of the midpoint potential of ubiquinone

1. 1. Cycles of oxidation followed by reduction at pH 7.2 have been induced in uncoupled anaerobic mung bean mitochondria treated with succinate and malonate by addition of oxygen-saturated medium. Under the conditions used, cytochromes b₅₅₇, b₅₅₃, c₅₄₉ (corresponding to c₁ in mammalian mitochondria) and ubiquinone are completely oxidized in the aerobic state, but become completely reduced in anaerobiosis.

2. 2. The time course of the transition from fully oxidized to fully reduced in anaerobiosis was measured for cytochromes c₅₄₉, b₅₅₇, and b₅₅₃. The intramitochondrial redox potential (IMP_h) was calculated as a function of time for each of the three cytochromes from the time course of the oxidized-to-reduced transition and the known midpoint potentials of the cytochromes at pH 7.2. The three curves so obtained are superimposable, showing that the three cytochromes are in redox equilibrium under these conditions during the oxidized-to-reduced transition.

3. 3. This result shows that the slow reduction of cytochrome b₅₅₇ under these conditions, heretofore considered anomalous, is merely a consequence of its more negative midpoint potential of +42 mV at pH 7.2, compared to +75 mV for cytochrome b₅₅₃ and +235 mV for cytochrome c₅₄₉. Cytochrome b₅₅₇ is placed on the low potential side of coupling site II and transfers electrons to cytochrome c₅₄₉ via the coupling site.

4. 4. The time course of the transition from fully oxidized to fully reduced was also measured for ubiquinone. Using the change in intramitochondrial potential IMP_h with time obtained from the three cytochromes, the change in redox state of ubiquinone with IMP_h was calculated. When replotted as IMP_h versus the logarithm of the ratio (fraction oxidized)/(fraction reduced), two redox components with n = 2 were found. The major component is ubiquinone with a midpoint potential E_m7.2 = + 70 mV. The minor component has a midpoint potential E_m7.2 = − 12 mV; its nature is unknown.

Identification of a stable ubisemiquinone and characterization of the effects of ubiquinone oxidation-reduction status on the Rieske iron-sulfur protein in the three-subunit ubiquinol-cytochrome c oxidoreductase complex of Paracoccus denitrificans

The ubiquinol-cytochrome c oxidoreductase (cytochrome bc1) complex from Paracoccus denitrificans exhibits a thermodynamically stable ubisemiquinone radical detectable by EPR spectroscopy. The radical is centered at g = 2.004, is sensitive to antimycin, and has a midpoint potential at pH 8.5 of +42 mV. These properties are very similar to those of the stable ubisemiquinone (Qi) previously characterized in the cytochrome bc1 complexes of mitochondria. The micro-environment of the Rieske iron-sulfur cluster in the Paracoccus cytochrome bc1 complex changes in parallel with the redox state of the ubiquinone pool. This change is manifested as shifts in the gx, gy, and gz values of the iron-sulfur cluster EPR signal from 1.80, 1.89, and 2.02 to 1.76, 1.90, and 2.03, respectively, as ubiquinone is reduced to ubiquinol. The spectral shift is accompanied by a broadening of the signal and follows a two electron reduction curve, with a midpoint potential at pH 8.5 of +30 mV. A hydroxy analogue of ubiquinone, UHDBT, which inhibits respiration in the cytochrome bc1 complex, shifts the gx, gy, and gz values of the iron-sulfur cluster EPR signal to 1.78, 1.89, and 2.03, respectively, and raises the midpoint potential of the iron-sulfur cluster at pH 7.5 from +265 to +320 mV. These changes in the micro-environment of the Paracoccus Rieske iron-sulfur cluster are like those elicited in mitochondria. These results indicate that the cytochrome bc1 complex of P. denitrificans has a binding site for ubisemiquinone and that this site confers properties on the bound ubisemiquinone similar to those in mitochondria. In addition, the line shape of the Rieske iron-sulfur cluster changes in response to the oxidation-reduction status of ubiquinone, and the midpoint of the iron-sulfur cluster increases in the presence of a hydroxyquinone analogue of ubiquinone. The latter results are also similar to those observed in the mitochondrial cytochrome bc1 complex. However, unlike the mitochondrial complexes, which contain eight to 11 polypeptides and are thought to contain distinct quinone binding proteins, the Paracoccus cytochrome bc1 complex contains only three polypeptide subunits, cytochromes b, c1, and iron-sulfur protein. The ubisemiquinone binding site and the site at which ubiquinone and/or ubiquinol bind to affect the Rieske iron-sulfur cluster in Paracoccus thus exist in the absence of any distinct quinone binding proteins and must be composed of domains contributed by the cytochromes and/or iron-sulfur protein.     

6-Pentyl-α-pyrone from Trichoderma harzianum: Its Plant Growth Inhibitory and Antimicrobial Properties

Gluconobacter suboxydans has a highly active respiratory chain which oxidizes several sugars and sugar alcohols. The results of this study indicate that the sugar-oxidizing respiratory chain consists of ubiquinone, several cytochromes c and a cytochrome o. The respiratory chain was shown to contain at least five cytochromes, including two cytochromes c associated with alcohol or aldehyde dehydrogenase, two cytochromes c that react with carbon monoxide and a single cytochrome o, some of which were characterized in this study. Furthermore, several lines of evidence suggest that the respiratory chain branchs at the site of ubiquinone with KCN-sensitive and -insensitive terminal oxidases, which may correspond to cytochrome o oxidase and an alternative oxidase consisting of a possible cytochrome c, respectively.     

The reconstitution of oxidative phosphorylation in mitochondria isolated from a ubiquinone-deficient mutant ofSaccharomyces cerevisiae

Mitochondria, isolated from the ubiquinone-deficient nuclear mutant ofSaccharomyces cerevisiae E3-24, are practically unable to oxidize exogenous substrates. Respiratory activity, coupled to ATP synthesis, can, however, be reconstituted by the simple addition of ethanolic solutions of ubiquinones. A minimal length of the isoprenoid side chain (3) was required for the restoration. Saturation of the reconstitution required a large amount of exogeneous ubiquinone, in excess over the normal content present in the mitochondria of the wild type strain. A similar pattern of reconstituted activities could be also obtained using sonicated inverted particles. Mitochondria and sonicated particles are also able to carry out a dye-mediated electron flow coupled to ATP synthesis in the absence of added ubiquinone, using ascorbate or succinate as electron donor. This demonstrates that the energy conserving mechanism at the third coupling site of the respiratory chain is fully independent of the presence of the large mobile pool of ubiquinone in the membrane.     

Evidence for a mobile semiquinone in the redox cycle of the mammalian cytochrome bc1 complex

Experimental evidence is presented to demonstrate that cytochromes b of the mammalian cytochrome bc1 complex may be rapidly oxidised by a pulse of oxidising equivalents which react with cytochrome c1, even when all cytochrome b is fully reduced before the pulse. The oxidation is sensitive both to antimycin and to myxothiazol. Such behaviour is inconsistent with models in which only the fully oxidised ubiquinone may move between the centres 'o' and 'i' of the complex. It is proposed that the charged semiquinone (Q-) may move between these centres, which may constitute separate reaction domains of a single ubiquinone-binding site. The bearing of this on the mechanism of electron, proton and charge transfer in the complex is discussed.     

Investigation of Endomyces magnusii respiratory system. Characteristics of mitochondria from cells grown in the presence of antimycin A]

Mitochondria from AA-cells are a unique model with separately finctioning 1st and 3rd points of energy coupling and with completely blocked 2nd coupling point. In vivo the terminal segment of the respiratory chain does not operate, cytochromes c and a+a3 remain oxidized, and dominating terminal oxidase appears to be a component inhibiting by salicylhydroxamate and bound with the respiratory chain via cytochromes b or ubiquinone pool. The blocking of the 2nd coupling point is due to firm and, probably, quantitative binding of AA with cytochromes b, especially with b559, and also to a partial denaturation of the complex III.     

Ascorbate-phenazine methosulfate-dependent membrane energization in respiratory chain mutants of Escherichia coli

Ascorbate with phenazine methosulfate was able to energize the membrane of inside-out membrane vesicles from cytochrome-containing but not cytochrome-deficient cells of the E., coli, hem A^? mutant SASX76 as measured by the quenching of the fluorescence of acridine dyes. This substrate could also energize vesicle membranes from the ubiquinone-deficient mutant E., coli AN59 in the absence of exogenous ubiquinone. These results suggest that there is site of membrane energization coupled to substrate oxidation in the respiratory chain of E., coli in the cytochrome region between ubiquinone and oxygen.     

Ubiquinol-cytochrome c oxidoreductase of higher plants. Isolation and characterization of the bc1 complex from potato tuber mitochondria.

A procedure is described for isolation of active ubiquinol-cytochrome c oxidoreductase (bc1 complex) from potato tuber mitochondria using dodecyl maltoside extraction and ion exchange chromatography. The same procedure works well with mitochondria from red beet and sweet potato. The potato complex has at least 10 subunits resolvable by gel electrophoresis in the presence of dodecyl sulfate. The fifth subunit carries covalently bound heme. The two largest ("core") subunits either show heterogeneity or include a third subunit. The purified complex contains about 4 mumol of cytochrome c1, 8 mumol of cytochrome b, and 20 mumol of iron/g of protein. The complex is highly delipidated, with 1-6 mol of phospholipid and about 0.2 mol of ubiquinone/mol of cytochrome c1. Nonetheless it catalyzes electron transfer from a short chain ubiquinol analog to equine cytochrome c with a turnover number of 50-170 mol of cytochrome c reduced per mol of cytochrome c1 per s, as compared with approximately 220 in whole mitochondria. The enzymatic activity is stable for weeks at 4 degrees C in phosphate buffer and for months at -20 degrees C in 50% glycerol. The activity is inhibited by antimycin, myxothiazol, and funiculosin. The complex is more resistant to funiculosin and diuron than the beef heart enzyme. The optical difference spectra of the cytochromes were resolved by analysis of full-spectrum redox titrations. The alpha-band absorption maxima are 552 nm (cytochrome c1), 560 nm (cytochrome b-560), and 557.5 + 565.5 nm (cytochrome b-566, which has a split alpha-band). Extinction coefficients appropriate for the potato cytochromes are estimated. Despite the low lipid and ubiquinone content of the purified complex, the midpoint potentials of the cytochromes (257, 51, and -77 mV for cytochromes c1, b-560, and b-566, respectively) are not very different from values reported for whole mitochondria. EPR spectroscopy shows the presence of a Rieske-type iron sulfur center, and the absence of centers associated with succinate and NADH dehydrogenases. The complex shows characteristics associated with a Q-cycle mechanism of redox-driven proton translocation, including two pathways for reduction of b cytochromes by quinols and oxidant-induced reduction of b cytochromes in the presence of antimycin.     

Cytochrome b of cob revertants in yeast. Bioenergetic characterization of revertants with reduced content and shifted maximum absorption wavelength of cytochrome b

22 revertants of Saccharomyces cerevisiae with intragenic suppressors (supa) of cob exon mutations (G. Burger, Mol. Gen. Genet., in the press) were analyzed. They display either a reduced amount of cytochrome b, or a shifted maximum absorption wavelength of total cytochrome b or a reduced growth rate on glycerol. The relationship of physico-chemical properties (content, light absorption and midpoint potential of cytochromes bK and bT) and functional properties (electron transport and energy yield) has been examined. In seven of eight revertants with a shifted maximum absorption wavelength of cytochrome b neither growth rate nor electron transfer activity was affected. In 13 of 14 revertants, reduced content of cytochrome b corresponds to a reduced electron transport rate through the cytochrome bc1 segment. A lower enzymatic activity, which is not due to a quantitative but to a qualitative alteration of cytochrome b was found in two revertants. Two revertants show electron transport rates of wild-type level concomitant with a reduced growth rate on glycerol, obviously due to a less efficient energy coupling. All revertants were shown to contain a high and a low potential cytochrome b, referred to as bK and bT. Those cob-/supa mutations which shift the maximum absorption wavelength or diminish the content of cytochrome b affect both b cytochromes in all cases. The results support that electron transport and energy conservation are catalyzed by the unity of cytochrome bK and bT and that both heme centers are bound to an identical apoenzyme. Comparing electron flow rates of succinate:cytochrome c oxidoreductase and NADH:cytochrome c oxidoreductase in cob- mutants and two revertants provides evidence that ubiquinone does not constitute a homogeneous pool, suggested by the dissimilar interaction of both dehydrogenases with the bc1 segment.     

Mutants of Escherichia coli K-12 Blocked in the Final Reaction of Ubiquinone Biosynthesis: Characterization and Genetic Analysis

The ubiquinone precursor 2-octaprenyl-3-methyl-5-hydroxy-6-methoxy-1, 4-benzoquinone was isolated from two ubiquinone-deficient mutants of Escherichia coli and identified by nuclear magnetic resonance and mass spectrometry. The results of genetic analysis of the mutants indicate that each mutant carries a mutation in a gene designated ubiG which was located, by cotransduction with the nalA and glpT genes, at minute 42 on the E. coli chromosome.