Benzoic acid inhibits Coenzyme Q biosynthesis in Schizosaccharomyces pombe

Coenzyme Q (CoQ, ubiquinone) is an essential component of the electron transport system in aerobic organisms. Human type CoQ10, which has 10 units of isoprene in its quinone structure, is especially valuable as a food supplement. Therefore, studying the biosynthesis of CoQ10 is important not only for increasing metabolic knowledge, but also for improving biotechnological production. Herein, we show that Schizosaccharomyces pombe utilizes p-aminobenzoate (PABA) in addition to p-hydroxybenzoate (PHB) as a precursor for CoQ10 synthesis. We explored compounds that affect the synthesis of CoQ10 and found benzoic acid (Bz) at >5 μg/mL inhibited CoQ biosynthesis without accumulation of apparent CoQ intermediates. This inhibition was counteracted by incubation with a 10-fold lower amount of PABA or PHB. Overexpression of PHB-polyprenyl transferase encoded by ppt1 (coq2) also overcame the inhibition of CoQ biosynthesis by Bz. Inhibition by Bz was efficient in S. pombe and Schizosaccharomyces japonicus, but less so in Saccharomyces cerevisiae, Aureobasidium pullulans, and Escherichia coli. Bz also inhibited a S. pombe ppt1 (coq2) deletion strain expressing human COQ2, and this strain also utilized PABA as a precursor of CoQ10. Thus, Bz is likely to inhibit prenylation reactions involving PHB or PABA catalyzed by Coq2.


Introduction
Coenzyme Q (CoQ), also called ubiquinone, is a component of the electron transport chain that participates in aerobic respiration in eukaryotes and most prokaryotes [1]. CoQ consists of a quinone ring and a hydrophobic isoprenoid side chain that has an all-trans configuration and a certain number of isoprene units [2]. The quinone moiety is reduced to form CoQH 2 (ubiquinol) from CoQ (ubiquinone), an essential component of electron transfer and oxidation-reduction enzymes, and an important antioxidant [3]. A CoQ-producing organism produces one type of CoQ as a main product, which is classified according to the length of the isoprenoid side chain [4]. For example, Homo sapiens and Schizosaccharomyces pombe predominantly produce CoQ 10  thiamine-repressible gene nmt1 of S. pombe [30] was used to overexpress the ppt1 gene. Wildtype (WT) cells transformed with pREP41 or pREP41-PPT1OR [31] were selected on PMU (PM containing uracil but lacking leucine) containing 10 μM thiamine and streaked onto the same media. For moderate ppt1 overexpression, transformants on the plate were grown in PMU liquid media containing 0.15 μM thiamine for 1 day at 30˚C. Cells were washed three times and transferred into PMU with or without 0.15 μM thiamine and incubated for 2 days at 30˚C. S. cerevisiae and A. pullulans cells were grown in complete YPD medium comprising 1% yeast extract (w/v), 2% glucose (w/v), and 2% HIPOLYPEPTON S (w/v). E. coli cells were grown in complete LB medium comprising 0.5% yeast extract (w/v), 1% NaCl (w/v), and 1% HIPOLYPEPTON S (w/v).

CoQ extraction and measurement
Fungi cells were pre-cultured in 10 mL of the indicated liquid medium for 1 day at 30˚C. E. coli cells were pre-cultured in 10 mL of LB for half a day at 37˚C. Each pre-culture was inoculated into a larger volume of medium, and the main culture was grown for the indicated time. Cell counts was measured using a Sysmex CDA-1000B cell counter (Sysmex, Tokyo, Japan) and optical density (OD) values were measured using a Shimadzu UVmini-1240 spectrophotometer (Shimadzu, Kyoto, Japan). At the indicated times, cells were harvested, and CoQ was extracted as described previously [10]. The CoQ crude extract was analyzed by normal-phase thin-layer chromatography (TLC) with authentic CoQ 6 or CoQ 10 standards. Normal-phase TLC was conducted on a Kieselgel 60 F 254 plate (Merck Millipore, MA, USA) and developed with benzene. The plate was viewed under UV illumination, the CoQ band was collected, and

Measurement of CoQ by liquid chromatography-mass spectrometry (LC-MS)
S. pombe cells cultured in YES medium for 1 day were transferred to fresh YES medium and cultured at 30˚C for 2 days. The initial cell density in YES was 1×10 5 cells/mL. CoQ was extracted as described above. LC-MS analysis was performed using a Xevo-TQ mass spectrometer (Waters, MA, USA) coupled to an ESCi multi-mode ionization source (Waters) that combines electrospray ionization (ESI) and atmospheric pressure chemical ionization (APCI). CoQ and related compounds were analyzed by APCI in positive mode (APCI+). Data acquisition and processing were performed using a MassLynx system (Waters). To detect the fragmented quinone ring of CoQ, LC-MS/MS was carried out using the product-ion-scan mode, and m/z 881, 887, and 867 ions of [M+NH 4 ] + forms were selected as precursor ions for CoQ 10 , ring-13 C 6 -CoQ 10 , and putative 2-methoxy-4-hydroxy-5-decaprenyl-benzoic acid, respectively. The conditions are listed in S1 Table.

Antibodies
To immunochemically detect CoQ biosynthetic proteins, rabbit polyclonal antisera were prepared by Sigma-Aldrich by injecting rabbits with specific peptides of Coq proteins [32]. The specificity of antisera against each of the CoQ biosynthetic proteins (Dlp1, diluted 1:1000; Coq4, diluted 1:500; Coq8, diluted 1:1000) was assessed by western blot analysis. Preparation of cell lysates and detection of CoQ biosynthetic proteins by immunoblotting S. pombe cell lysates were performed as described previously [33]. WT S. pombe (PR110) cells were inoculated into 55 mL YES main cultures with or without Bz (initial cell density~1×10 5 cells/mL) and incubated with rotation at 30˚C for 2 days, and then harvested. For mitochondria isolation, WT S. pombe (PR110) cells were cultivated in 1.5 L YES or YES with 25 μg/mL Bz (initial OD 600~0 .05, cultivated for 20 h with rotation at 30˚C) and mitochondria-enriched samples were prepared as described previously [34]. Lysate proteins were separated by SDS-PAGE, after which western blot analysis was performed using an ECL detection system (GE Healthcare, IL, USA). Rabbit polyclonal antibodies against the PSTAIRE peptide (Cdc2, diluted 1:1000) were purchased from Santa Cruz Biotechnology. Horseradish peroxidase-conjugated anti-rabbit IgG antibody (Promega, WI, USA) was used as secondary antibody (diluted 1:2000). These antibodies were dissolved in a Can Get Signal immunoreaction enhancer solution (TOYOBO, Osaka, Japan). For quantification of protein bands, Image J (https://imagej. nih.gov/ij/download.html) was used.

Data and statistical analyses
All experiments were performed at least three times, and average values and standard deviation (SD) were calculated except for S7 and S8 Figs. Data from control and target samples were compared using the two-sample t-test in Microsoft Excel (Microsoft, WA, USA), and p-values <0.05 were considered statistically significant.

S. pombe utilizes PABA as a precursor in CoQ synthesis
In addition to PHB, PABA is utilized as a precursor in CoQ synthesis in S. cerevisiae [20,21,35], the sole species known to utilize PABA for CoQ synthesis. Therefore, we first tested whether PABA is also utilized in S. pombe. 13 C 6 labeled-PABA or 13 C 6 labeled-PHB was incubated with the S. pombe PR110 strain and the lipid fraction was extracted. After the CoQ 10enriched fraction was separated by TLC, 13 C 6 -CoQ 10 was measured by LC-MS. When 1 μg/mL 13 C 6 -PHB was incubated, 13 C 6 -labeled CoQ 10 , which yields an [M+NH 4 ] + ion product with a mass 6 Da (886.5) higher than that of none-labeled CoQ 10 [M+NH 4 ] + (880.5), was detected by MS (Fig 1). After fragmentation of this product, a tropylium ion derivative, an aromatic species with the formula [C 7 H 7 ] + , was generated. As a result, an [M] + ion with a mass of 202.7, which has a mass 6 Da higher than that of the non-labeled tropylium ion [M] + (196.7), was detected. About 88% of the total CoQ pool was labeled with 13 C 6 derived from 13 C 6 -PHB. Similarly, when cells were incubated with 13 C 6 -PABA, a 13 C 6 -CoQ 10 product with a 6 Da increase was detected. About 60% of the total CoQ pool was labeled with 13 C 6 derived from 13 C 6 -PABA. This result shows that PABA was efficiently utilized as a precursor of CoQ synthesis in S. pombe, similar to S. cerevisiae. Additionally, exogenous 13 C 6 -PHB was more efficiently incorporated in CoQ 10 than 13 C 6 -PABA. PABA and PHB are metabolized to supply quinone for CoQ 10 synthesis in S. pombe. S. pombe wild-type (WT) PR110 cells were pre-cultivated in 10 mL YES medium for 1 day, 1 μg/mL of 13 C 6 -PABA or 13 C 6 -PHB was added to 55 mL of YES media containing 1×10 5 cells/mL, and the cells were cultivated for 2 days with rotation at 30˚C. CoQ 10 -enriched samples were obtained after separation of lipids by TLC, and samples were subjected to LC-MS and LC-MS/MS (daughter scan) analyses to detect stable isotope-labeled CoQ 10 . https://doi.org/10.1371/journal.pone.0242616.g001

Bz is an inhibitor of CoQ biosynthesis in S. pombe
S. pombe is an excellent microorganism for increasing the production of CoQ 10 [31,32], as well as for studying the pathway of CoQ 10 synthesis, which could lead to the identification of human orthologous enzymes [36,37]. To obtain a better understating of CoQ 10 synthesis, we examined analogous compounds of PABA or PHB that may alter CoQ synthesis in S. pombe. We tested the effect of Bz, 4-nitrobenzoic acid (4-NB), 4-chlorobenzoic acid (4-ClBz), and 2,4-dihydroxy benzoic acid, also known as 2,4-DiHB or β-resorcylic acid (β-RA) (S2 Fig). Although we did not identify a compound that enhanced CoQ 10 production in S. pombe, we found that Bz, 4-ClBz, and 2,4-DiHB inhibited CoQ synthesis (Fig 2A). In the case of 2,4-DiHB treatment, an intermediate-like compound, probably 2-methoxy-4-hydroxy-5-decaprenyl-benzoic acid, was accumulated ( Fig 2B, 2C and 2D). However, 4-nitrobenzoic acid (4-NB), an inhibitor of COQ2 in mammalian cells [22], did not inhibit CoQ production in S. pombe, although it moderately inhibited cell growth. Bz treatment most effectively lowered S. pombe CoQ 10 production. Bz at 5 μg/mL or higher concentrations significantly decreased the CoQ 10 level ( Fig 3A). Incubation with 10 μg/mL (81.9 μM) Bz and 100 μg/mL (819 μM) Bz resulted in decreases of~50% and 87% in the CoQ 10 level (μg/10 9 cells), respectively. Incubation with 10 μg/mL Bz for 2 days decreased cell number to 74% of that of the controls, but did not affect dry cell weight (DCW) ( Table 2). However, incubating with 100 μg/mL Bz for 2 days decreased both cell number and DCW. Significantly, 10 μg/mL Bz and 100 μg/mL Bz decreased CoQ 10 /DCW by 42% and 9%, respectively, compared with cells not treated with Bz. The L972 strain, a WT strain with no auxotrophy (S3 Fig), showed a similar reduction in CoQ 10 after treatment with 100 μg/mL Bz, indicating that the effect of Bz was not straindependent. We did not observe any accumulation of any intermediate compound such as prenylated benzoic acid by MS analysis in the wild type cells incubated with benzoic acid. We tested the effect of Bz on Colony Forming Unit (CFU) of PR110 strain. Bz did not significantly affect CFU (S4A Fig; gray  We also measured the amount of mitochondrial CoQ 10 after separating the mitochondriaenriched fraction by several centrifugation steps, as described in the Materials and Methods. Bz treatment decreased the mitochondrial CoQ 10 concentration to that equivalent to the decrease in the total cellular CoQ 10 level (Fig 3B and 3C). Additionally, in order to explore whether Bz promotes the degradation of CoQ 10 , we evaluated the effect of adding Bz to a dense cell culture (1×10 7 cells/mL). After 2 h of cultivation, no significant decrease in CoQ 10 level was observed following addition of Bz, and there was no significant change in the amount of CoQ 10 (μg/50 mL medium) after treatment for 7 h (S5A Fig). From these observations, we concluded that addition of Bz did not promote the decomposition of CoQ.
In addition, we measured the amount of CoQ 10 after long-term cultivation up to 75 h starting from 1.5×10 6 cells/mL. Under these conditions, the amount of CoQ in cells reached the upper limit (~10.0 μg/10 9 cells) without Bz, but it gradually increased following addition of Bz at 100 μg/mL (S5B Fig). This result indicates that although Bz inhibits CoQ biosynthesis, it does not completely block its synthesis.
Because the addition of Bz to YES complete medium lowered the pH to 5.6 from 6.0, we tested the effect of sodium benzoate (BzNa), which does not alter medium pH. The results revealed similar growth inhibition and decreases in the CoQ level for Bz and BzNa treatments at the same molar concentration (S6 Fig), suggesting that the decrease in pH caused by Bz treatment was not responsible for its negative effects on growth and the CoQ level in S. pombe.

PABA or PHB can restore CoQ levels decreased by Bz
We subsequently investigated the effect of PABA or PHB on the inhibition of CoQ 10 biosynthesis by Bz. PABA or PHB (1 μg/mL) restored CoQ levels decreased by 10 μg/mL Bz treatment; 1 μg/mL (7.24 μM) PHB and 10 μg/mL (72.9 μM) PABA restored CoQ levels decreased by 100 μg/mL Bz treatment (Fig 4). This further indicates that PABA is utilized as a precursor in CoQ synthesis. PHB was more efficient than PABA at reversing the CoQ reduction following high-level Bz treatment. Co-treatment with PABA or PHB did not restore cell growth inhibited by Bz, indicating that Bz does not decrease CoQ levels by lowering cell growth. We did not observe any clear increase in CoQ 10 production in S. pombe following treatment with PABA or PHB alone.
It has been shown that analogs of PHB such as 4-NB can inhibit human Coq2 [22], suggesting that S. pombe Ppt1 (Coq2) might be a potential target of Bz. If this is the case, overexpression of ppt1 (coq2) would counteract inhibition by Bz. To investigate CoQ production in the ppt1 (coq2)-overexpressing strain, we employed plasmid pREP41-PPT1OR, which contains ppt1 from S. pombe under the control of the nmt1 thiamine-repressible promoter. As expected, ppt1 overexpression abolished the decrease in the CoQ level caused by 10 μg/mL Bz treatment (Fig 5). Additionally, treatment with a lower concentration of PABA or PHB revealed an additive increase in CoQ production following ppt1 overexpression in S. pombe in Bz-containing medium. In human, 4-NB inhibits CoQ biosynthesis, but the effect of Bz is unknown [22]. Therefore, a ppt1 disruptant yeast strain expressing human COQ2 (1stM-HsCOQ2 and 4thM-HsCOQ2 [10]) under the control of the nmt1 thiamine-repressible promoter was used to test CoQ production following Bz or 4-NB treatment. When human COQ2 was expressed in a fission yeast strain lacking ppt1 (coq2), Bz inhibited CoQ production while 4-NB moderately inhibited CoQ production (Fig 6), and the addition of PABA or PHB restored CoQ production inhibited by Bz. This result indicates that Bz could potentially inhibit human CoQ production.
We next tested whether PABA is utilized in an artificial S. pombe ppt1 (coq2) deletion strain expressing human COQ2. The results revealed that exogenously added 2 μM 13 C 6 -PABA was effectively incorporated to produce CoQ 10 in KH2 (Δppt1)/pREP1-1stM-HsCOQ2 and KH2 (Δppt1)/pREP1-4thM-HsCOQ2 strains, as well as in the WT strain (S7 Fig). Following addition of 13 C 6 -PABA, CoQ 10 levels in Δppt1 strains expressing human COQ2 were about fourfold higher than without PABA (S7 Fig). Utilization of PABA in human cells has not been confirmed, but our results indicate that human CoQ2 accepts PABA, and if the later pathway leading to CoQ is available, PABA would be utilized for CoQ synthesis in human.

Phenotypic effects of Bz incubation
CoQ-deficient mutants such as the ppt1 (coq2) disruptant cannot grow on medium containing glycerol and ethanol as non-fermentable carbon sources [14,38], but they can grow on extraction. Protein concentration was measured by a Bio-Rad protein assay kit. (A−C) Asterisks on bars denote statistically significant differences ( �� p<0.01, � p<0.05) relative to samples from YES without Bz (Student's t-test). https://doi.org/10.1371/journal.pone.0242616.g003

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medium containing a fermentative carbon source such as glucose (Fig 7A). We thought that Bz treatment may reduce growth on a medium containing a non-fermentable carbon source, due to reduction of CoQ synthesis. However, cell growth on non-fermentable media containing Bz was not distinguishable from that without Bz (Fig 7A). Also, the CoQ level was lower in cells grown in glycerol and ethanol with Bz than without ( Fig 7B). Thus, Bz did not negatively affect cell growth in medium containing a non-fermentable carbon source in S. pombe. CoQ is an electron acceptor for sulfide-quinone oxidoreductase, and high production of sulfide is observed in CoQ-deficient fission yeast [39]. Therefore, the sulfide level under Bz treatment was tested, but it was not altered (S8 Fig). This is probably because inhibition by Bz does not completely abolish CoQ synthesis (Fig 3).

Inhibition by Bz lowers Coq protein levels
It has been shown that the biosynthetic enzymes responsible for CoQ form a multi-enzyme complex in S. cerevisiae [40], and Coq4 is the central organizer [41,42]. We believe that the same may be true for S. pombe, based on our preliminary data. Therefore, the effect of Bz on Coq protein levels was analyzed, and the results showed that the Coq4 and Coq8 proteins decreased after adding �5 μg/mL Bz (Fig 8A). However, the Dlp1 protein level was not changed by Bz treatment. A similar trend of low abundance of the Coq4 protein, but not the Coq8 protein, by Bz inhibition was observed in isolated mitochondria (Fig 8B). When the abundance of the Coq4 protein was tested in Δppt1 strain, it was a comparable level of wild type cells incubated with 100μg/mL Bz (Fig 8C), which support the idea that Bz inhibits the Ppt1 (Coq2) reaction. Overexpression of the coq4 gene did not restore the production of

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CoQ 10 reduced by Bz inhibition (S9 Fig), therefore, it is unlikely that the reduction of the Coq4 protein is a sole reason for lowering CoQ 10 production by Bz. We think that a decrease in Coq protein expression destabilizes the Coq multi-enzyme complex, but further studies employing antibodies specific for other Coq proteins will be needed to test this hypothesis.

Inhibition of CoQ synthesis in other microorganisms
We next explored whether Bz inhibits CoQ synthesis in other microorganisms. The effect of Bz was moderate in S. cerevisiae, even at a concentration of 100 μg/mL (Fig 9A), and no inhibition was observed in A. pullulans (Fig 9B). Inhibition of CoQ synthesis by Bz was clearly observed at a 10-fold lower concentration (10 μg/mL) in S. japonicus using two independent strains (Fig 9C and 9D), although the amount of CoQ was very low in these species. The effect of Bz on E. coli was also moderate (Fig 9E). Thus, inhibition by Bz is much more efficient in S. pombe and S. japonicus than in S. cerevisiae and E. coli.

Discussion
In the present study, we showed that PABA is utilized for CoQ synthesis in S. pombe, as was demonstrated previously for S. cerevisiae. PHB is commonly utilized as a precursor of CoQ in both prokaryotes and eukaryotes [8]. However, exactly how widely PABA is utilized for CoQ synthesis is not yet clear. For example, human and E. coli do not utilize PABA for CoQ synthesis, probably because the pathway to modify the prenylated PABA leading to the synthesis of CoQ is lacking [24]. It has been reported that exogenous PABA is prenlyated by prenlytransferase in mammalian tissues [24], hence mammalian COQ2 must be able to conjugate PABA with polyprenyl diphosphate. When we examined the effect of PABA in the S. pombe ppt1 (coq2) deletion strain expressing human COQ2, PABA counteracted the inhibitory effect of Bz on the synthesis of CoQ. Since S. pombe possesses the pathway to synthesize CoQ from PABA, human COQ2 appears to be able to prenylate PABA. Furthermore, replacing S. pombe ppt1 (coq2) with human COQ2 made it possible to synthesize CoQ from PABA. Although utilization of PABA as a precursor of CoQ in human cells has not been proved, our results indicate that human COQ2 accepts PABA as a substrate. This is the first study to report the effect of Bz on CoQ synthesis in S. pombe. We think that Bz is likely to be an inhibitor of prenylation of PABA and PHB by Ppt1 (Coq2) for two reasons. Firstly, inhibition by Bz was reversed by an~10-fold lower concentration of PABA and PHB,  [10] were cultivated in 55 mL PMU medium containing 0.32 mg/mL cysteine and 0.15 μg/mL thiamine for 2 days. Cells were washed three times with distilled water and inoculated into 55 mL PMU medium containing 0.32 mg/mL cysteine (initial cell density~1×10 6 cells/mL) and cultivated for 2 days with rotation at 30˚C. Next, 2 μg/mL PABA, 2 μg/mL PHB, 10 μg/mL Bz, or 100 μg/mL 4-NB was added to the media to test their effects. Gray bars show the CoQ 10 content per 50 mL of medium, and white bars show CoQ 10 normalized against cell number. Diamonds show cell number. Five micrograms of CoQ 6 was used as an internal standard. Data are represented as the mean ± SD of two (A) or three (B) measurements. Asterisks on bars denote statistically significant differences ( �� p<0.01, � p<0.05) relative to PMU + cysteine (Student's t-test).
https://doi.org/10.1371/journal.pone.0242616.g006 and this inhibition was overcome by overexpression of ppt1 (coq2) gene. These observations support the idea that Bz targets Ppt1 (Coq2). In previous reports, in vitro assay analysis of the prenylation of several compounds indicated that PABA, vanillic acid, and protocatechuic acid are prenlylated in rat [24]. Although Bz was not tested in this experiment, Coq2 has a broad substrate spectrum and accepts a wide range of related compounds.
Addition of Bz lowered the abundance of the Coq4 protein. This suggests that once the enzymatic reaction of CoQ synthesis is halted by an inhibitor, at least the Coq4 protein becomes unstable (Fig 8). We did not see such an effect in the Dlp1 protein, presumably because Dlp1 is separated from the complex of CoQ synthesis in S. pombe. S. pombe likely forms a complex of CoQ synthetic enzymes (our unpublished observations). The enzymatic complex responsible for CoQ synthesis, named the Q synthome, has been well studied in S. cerevisiae [18], and PHB stabilizes the Q synthome [42]. It has also been shown that the expressions of COQ genes including COQ4 in S. cerevisiae is not affected by loss of Q synthome formation [44]. All together suggest the proper formation of the CoQ synthetic enzyme complex affects the protein stability of Coq4, but not the expression of coq4, in S. pombe. Further studies are needed to reveal more about complex stability. Growth and CoQ 10 production of yeast growing on the non-fermentable carbon source YEGES following Bz treatment. (A) S. pombe strains were spotted onto YES or YEGES with or without 100 μg/mL Bz. Cells grown on YES for 1 day were washed three times. A culture with an OD 600 of 2 was serially diluted from 10 −1 to 10 −5 (from left to right), spotted onto agar media, and cultured for 7 days. (B) For the pre-culture, PR110 yeast cells were cultivated in 55 mL of normal YES medium for 1 day, washed three times with pure water, and 100 μg/mL of benzoic acid (Bz) was added to YEGES media containing 2% (w/v) glycerol and 1% ethanol (w/v) instead of 3% glucose (w/v) with an initial cell density of~1×10 7 cells/mL, and cells were cultivated for 3 days at 30˚C. Gray bars show the CoQ 10 content per 50 mL medium, and white bars show CoQ 10 normalized against cell number. Five micrograms of CoQ 6 was used as an internal standard for CoQ extraction. Data are represented as the mean ± SD of three measurements. Asterisks on bars denote statistically significant differences ( �� p<0.01, � p<0.05) relative to YEGES without Bz (Student's t-test). https://doi.org/10.1371/journal.pone.0242616.g007 Bz clearly inhibits CoQ synthesis in S. japonicus, although the amount of CoQ is very low in this species (~100 times lower than in S. pombe) [38]. We observed moderate inhibition of CoQ by Bz in S. cerevisiae and E. coli, but almost no inhibition in A. pullulans. We think that differences in inhibition are not due to the specificity of Coq2, because we observed inhibition by Bz in S. pombe cells expressing human COQ2. COQ2 and its homolog are interchangeable among species; S. cerevisiae COQ2 is functionally exchangeable with UbiA in E. coli [45] and an Arabidopsis PPT1 (COQ2) homolog with S. cerevisiae COQ2 [46]. If the specificity of Bz to various Coq2 homologs is not so strict, differences in the inhibitory effect of Bz on CoQ synthesis among different organisms might be due to differences in how effectively Bz is transported inside cells [47] and into mitochondria. On the contrary, the observation in this study

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that an inhibitory effect of 4-NB was not observed in S. pombe but observed in S. pombe having replaced with human COQ2, might suggest this difference is due to the difference in substrate recognition among Coq2 homologs. To clarify these aspects, further studies will be required for precise inhibitory mechanism of these compounds.
Bz and BzNa have been widely used as food additives to inhibit the growth of microorganisms in foods and soft drinks [48,49]. Bz is considered generally safe at a concentration up to  [43], S. japonicus NIG2021, S. japonicus isolated from a Kinzaki ancient tomb located in Matsue [38], and E. coli DH5α cells were cultivated in 10 mL of the indicated medium for 1 day. To explore the inhibitory effect of Bz, the indicated amount (μg/mL) of Bz was added to the media. For fungi, the initial cell density was~1×10 5 cells/mL and cells were cultivated for 2 days with rotation at 30˚C; for E. coli, the initial cell density was OD 600 0.1 and cells were cultivated for 12 h with rotation at 37˚C. Gray bars show the CoQ 10 content per 50 mL of medium, and white bars show CoQ 10 normalized against cell number. Diamonds show cell number or optical density. Five micrograms of CoQ 6 was used as an internal standard for measuring CoQ 8 , CoQ 10 , or CoQ 10 (H 2 ), which is CoQ 10 with a saturated isoprenoid unit in the side chain. Five micrograms of CoQ 10 was used as an internal standard for measuring CoQ 6 . Data are represented as the mean ± SD of three measurements. Asterisks on bars denote statistically significant differences ( �� p<0.01, � p<0.05) relative to each medium without Bz (Student's t-test).
https://doi.org/10.1371/journal.pone.0242616.g009 0.1%, which is 10 times higher than 100 μg/mL concentration employed in this study. At a concentration of 100 μg/mL of Bz, growth of S. pombe was clearly inhibited, but not that of S. cerevisiae and A. pullulans. We again speculate that differences in growth inhibition among the tested species may be due to differences in the uptake efficiency of this compound, resulting in differences in the inhibitory effect of Bz on CoQ synthesis. While plants synthesize Bz [50,51], yeasts do not, and how Bz is metabolized in yeasts is not well understood. In yeasts, at least in S. pombe, Bz is an unfavorable compound for cell growth.
In conclusion, we demonstrated that PABA is efficiently utilized as a precursor of CoQ synthesis in S. pombe. Bz inhibits S. pombe CoQ synthesis, presumably by inhibiting the PHB/ PABA prenyl transferase enzyme encoded by ppt1 (coq2).
Supporting information S1 Fig. CoQ biosynthesis in S. pombe. In this study, PABA was shown to be utilized as a precursor for a quinone ring in addition to PHB in S. pombe. Decaprenyl diphosphate, which is synthesized by decaprenyl diphosphate synthase (Dps1 + Dlp1), is transferred to PABA or PHB by PABA/PHB-decaprenyl diphosphate transferase (Ppt1, Coq2), and the aromatic ring is then modified during CoQ biosynthesis. DAB, 5-decaprenyl-4-aminobenzoic acid; DHB, 5-decaprenyl-4-hydroxybenzoic acid; DPP, decapentenyl diphosphate; FPP, farnesyl diphosphate; IPP, isopentenyl diphosphate; PABA, p-aminobenzoic acid; PHB, p-hydroxybenzoic acid. For the pre-culture, PR110 yeast cells were cultivated in 55 mL medium for 1 day. Cells at an initial cell density of 1×10 7 cells/mL (A) or 1.5×10 6 cells/mL (B) were grown with or without 100 μg/mL of benzoic acid (Bz) and cultivated for the indicated time with rotation at 30˚C. Gray bars show the CoQ 10 content per 50 mL medium, and white bars show CoQ 10 normalized against cell number. Five micrograms of CoQ 6 was used as an internal standard for CoQ extraction. Data are represented as the mean ± SD of three measurements. Asterisks on bars denote statistically significant differences ( �� p<0.01) relative to the 0 h (A) or 12 h timepoint (B) without Bz (Student's t-test). For the pre-culture, WT PR110 yeast cells harboring pREP1, KH2 (Δppt1) harboring pREP1-1stM-HsCOQ2, or pREP1-4thM-HsCOQ2 were cultivated in 10 mL PMU medium containing 0.32 mg/mL cysteine and 0.15 μg/mL thiamine for 2 days. Cells were washed three times with distilled water and inoculated into 55 mL PMU medium containing 0.32 mg/mL cysteine (initial cell density~2×10 6 cells/mL) and cultivated for 1 day with rotation at 30˚C. A 2 μg/mL sample of 13 C 6 -PABA was added to confirm the incorporation to the quinone ring of CoQ. CoQ 10 -enriched samples were obtained after separation of lipids by TLC, and samples were subjected to LC-MS and LC-MS/MS (daughter scan) analyses to detect stable isotopelabeled CoQ 10 . In PR110/pREP1 (A), KH2 (Δppt1)/ pREP1-1stM-HsCOQ2 (B), and KH2 (Δppt1)/pREP1-4thM-HsCOQ2 (C) strains, samples were prepared with and without 2 μg/mL Yeast cells were grown in YES for indicated times and H 2 S concentrations were measured by the method described previously [39]. (TIFF) S9 Fig. CoQ 10 production by the coq4-overexpressing strain treated with 10 μg/mL or 100 μg/mL Bz. WT PR110 cells harboring pREP1 (Vector) or pREP1-Spcoq4 (+coq4) [31] were cultivated in 10 mL PMU containing 0.15 μg/mL thiamine for 1 day. 0.15 μg/mL thiamine was added to repress the expression of the nmt1 promoter, and 10 μg/mL and 100 μg/mL of Bz were also added to the media containing~1×10 6 cells/mL and the cells were cultivated for one day with rotation at 30˚C. Gray bars show the CoQ 10 content per 50 mL of medium, and white bars show CoQ 10 normalized against cell number. Diamonds show cell number. Five micrograms of CoQ 6 was used as an internal standard. Data are represented as the mean ± SD of two measurements. (TIFF) S1 Table. LC-MS conditions. (DOCX) S1 Raw image. (ZIP) with high fat diet. Antioxidants (Basel). 2020; 9:431. https://doi.org/10.3390/antiox9050431 PMID: