L-tyrosine is the precursor of PQQ biosynthesis in Hyphomicrobium X

A method was developed to study amino acids as possible precursors of PQQ biosynthesis. Cultures of Hyphomicrobium X, growing on [13C]methanol, were supplemented with unlabelled amino acids. Uptake and participation in metabolism were determined via gas chromatography/mass spectrometry of derivatized amino acids, obtained from hydrolyzed cellular protein, by measuring their 12C content. Several amino acids appeared to be incorporated into the protein to a significant extent, without degradation or conversion. Among these were the aromatic amino acids, L-tyrosine and L-phenylalanine. Using the same replacement approach, their incorporation into PQQ was determined by 1H- and 13C-NMR spectroscopy of purified PQQ obtained from the culture medium. It appeared that the complete carbon skeleton of tyrosine was present, forming the o-quinone and pyrrole-2-carboxylic acid moieties in PQQ, while phenylalanine was not incorporated at all. Starting with L-tyrosine, possible biosynthetic routes to PQQ are discussed.     

Acid-promoted tautomeric lactonization and oxidation-reduction of pyrroloquinoline quinone (PQQ)

Acid-treatment facilitates PQQ detection by electron ionization mass spectroscopy with a molecular ion at M/e 330 and a base ion formed by triple decarboxylation at M/e 198. Other ions found probably arise through acid-catalyzed tautomeric lactonization of PQQ to PQQ-lactone (PQQL) with subsequent oxidation of PQQL and reduction of PQQ. We propose that a carboxyl group, presumably the 9-carboxyl, attacks a double bond in PQQ, reversibly converting the 4,5-orthoquinone into an 4,5-enediol and forming an isomeric lactone, PQQL, of 330 daltons. The masking of carbonyls may explain the low reactivity of PQQ with carbonyl reagents in acid. Acid-promoted tautomeric lactonization with carbonyl-masking is known to occur with fluoresceins, phenolphthalein and other compounds, but has not been recognized before with PQQ. Acid-treated PQQ demonstrates molecular and other ions derived from reduced PQQ (PQQ(2H] or its lactone at M/e 332 with a base ion at M/e 200. There is compelling evidence for a dehydrogenated lactone, PQQ(-2H)L), at M/e 328 with a base ion at M/e 196. We suggest that PQQ, in tautomeric equilibrium with PQQL, oxidizes PQQL to PQQ(-2H)L (328 daltons), with its concurrent reduction to PQQ(2H) (332 daltons). With acidified D2O, PQQ shows deuterated products with ions at M/e values consistent with lactonization and oxidation-reduction. An analytically useful quinoxaline adduct, formed from PQQ and 2,3-diaminonaphthalene (PQQ-DAN) of 452 daltons, also undergoes acid-tautomerization-lactonization and oxidation-reduction similar to PQQ showing molecular ions at M/e 450, 452 and 454 and decarboxylation-derived strong (base) ions at M/e 318, 320 and 322.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cloning of Klebsiella pneumoniae pqq genes and PQQ biosynthesis in Escherichia coli

We have cloned genes from Klebsiella pneumoniae which are required for pyrroloquinoline quinone (PQQ) biosynthesis. The cloned 6.7 kb fragment can complement several chromosomal pqq mutants. Escherichia coli strains are unable to synthesize PQQ but E. coli strains containing the cloned 6.7 kb K. pneumoniae fragment can synthesize PQQ in large amounts and E. coli pts mutants can be complemented on minimal glucose medium by this clone.     

PQQ and quinoprotein research--the first decade

On the occasion of the first international symposium on pyrroloquinoline quinone (PQQ) and quinoproteins (Delft, September 1988), a review of this novel field in enzymology is presented. Quinoproteins (PQQ-containing enzymes) are widespread, from bacteria to mammalian organisms (including man), and occur in several classes of enzymes. Indications already exist that PQQ is a versatile cofactor, involved not only in oxidation but also in hydroxylation, transamination, decarboxylation and hydration reactions. The current list of quinoproteins shows that it was overlooked in several well-studied enzymes where the presence of a common cofactor had already been established. Up until now, all eukaryotic quinoproteins have covalently bound PQQ (or perhaps pro-PQQ), while free PQQ occurs exclusively in a number of (bacterial) dehydrogenases and in the culture fluid of certain Gram-negative bacteria. Biosynthesis of free PQQ in methylotrophic bacteria starts with tyrosine and glutamic acid as precursors while intermediates in the route have not been detected and the presence of free PQQ is not required for synthesis of the covalently bound form of the cofactor in glutamic acid decarboxylase from Escherichia coli. Therefore, the assembly of covalently bound cofactor might occur in situ, i.e. in the quinoproteins themselves. If the latter also applies to mammalian quinoproteins, this implies that PQQ is not a vitamin. On the other hand, positive effects have been reported upon administration of PQQ to test animals. Methods suited to detach and to detect PQQ with a derivatized o-quinone moiety may answer questions on the uptake and processing of the compound.     

PQQ: Biosynthetic studies inMethylobacterium AM1 andHyphomicrobium X using specific13C labeling and NMR

Using¹³C labeling and NMR spectroscopy we have determined biosynthetic precursors of pyrroloquinoline quinone (PQQ) in two closely related serine-type methylotrophs,Methylobacterium AM1 andHyphomicrobium X. Analysis of the¹³C-labeling data revealed that PQQ is constructed from two amino acids: the portion containing N-6,C-7,8,9 and the two carboxylic acid groups,C-7 and 9, is derived-intact-from glutamate. The remaining portion is derived from tyrosine; the phenol side chain provides the six carbons of the ring containing the orthoquinone, whereas internal cyclization of the amino acid backbone forms the pyrrole-2-carboxylic acid moiety. This is analogous to the cyclization of dopaquinone to form dopachrome. Dopaquinone is a product of the oxidation of tyrosine (via dopa) in reactions catalyzed by monophenol monooxygenase (EC 1.14.18.1). Starting with tyrosine and glutamate, we will discuss possible biosynthetic routes to PQQ.     

Biosynthesis of thiamine. Incorporation experiments with 14C-labelled substrates and with [15N]glycine in Saccharomyces cerevisiae

1. Yeast was grown in a minimal synthetic medium together with a range of (14)C-labelled substrates under standardized conditions. After isolation, the purified thiamine was cleaved by sulphite and the pyrimidine and thiazole moieties were purified and assayed for radioactivity. 2. In order of decreasing incorporation, [(14)C]formate, [3-(14)C]serine, [2-(14)C]glycine and [2-(14)C]acetate supplied label for the pyrimidine, and [2-(14)C]glycine, [3-(14)C]serine, [1-(14)C]glycine, [(14)C]formate and [2-(14)C]acetate for the thiazole. Incorporation of label into the fragments from several other (14)C-labelled substrates, including [Me-(14)C]- and [3,4-(14)C(2)]-methionine, was insignificant. 3. [3-(14)C]Serine was shown not to contribute label to C-2 of the thiazole ring. 4. Significant incorporation of nitrogen from [(15)N]glycine into the thiazole moiety, but not into the pyrimidine moiety, was established. 5. It appears that C-2 and N-3 of the thiazole ring are formed from C-2 and the nitrogen atom of glycine, but the entire methionine molecule does not appear to be implicated.     

Identification of Pantoea ananatis gene encoding membrane pyrroloquinoline quinone (PQQ)-dependent glucose dehydrogenase and pqqABCDEF operon essential for PQQ biosynthesis

Pantoea ananatis accumulates gluconate during aerobic growth in the presence of glucose. Computer analysis of the P. ananatis SC17(0) sequenced genome revealed an ORF encoding a homologue (named gcd) of the mGDH (EC 1.1.99.17) apoenzyme from Escherichia coli and a putative pyrroloquinoline quinone (PQQ) biosynthetic operon homologous to pqqABCDEF from Klebsiella pneumoniae. Construction of Δgcd and Δpqq mutants of P. ananatis confirmed the proposed functions of these genetic elements. The P. ananatis pqqABCDEF was cloned in vivo and integrated into the chromosomes of P. ananatis and E. coli according to the Dual In/Out strategy. Introduction of a second copy of pqqABCDEF to P. ananatis SC17(0) doubled the accumulation of PQQ. Integration of the operon into E. coli MG1655ΔptsGΔmanXY restored the growth of bacteria on glucose. The obtained data show the essential role of pqqABCDEF in PQQ biosynthesis in P. ananatis and E. coli. We propose that the cloned operon could be useful for an efficient phosphoenolpyruvate-independent glucose consumption pathway due to glucose oxidation and construction of E. coli strains with the advantage of phosphoenolpyruvate-derived metabolite production.     

PQQ and quinoprotein enzymes in microbial oxidations

Abstract Pyrroloquinoline quinone (PQQ) is found in a wide range of microorganisms, and several bacteria even excrete this compound into their culture medium when grown on alcohols. The existence of different classes of quinoprotein (PQQ-containing) enzymes is now well established (alcohol dehydrogenases, aldose (glucose) dehydrogenases, amine dehydrogenases and amine oxidases) while several other enzymes are suspected to be quinoproteins. In addition, many bacteria produce a quinoprotein apoenzyme, e.g., Escherichia coli and Pseudomonas testosteroni , producing glucose and ethanol dehydrogenase apoenzyme, respectively. It is unclear why these bacteria do not produce the holoenzyme form, but the apoenzymes have the ability to become functional, as was shown when the organisms were provided with PQQ. With this approach it could be demonstrated that E. coli has a non-phosphorylative route of glucose dissimilation via gluconate. Also, results with mixed cultures indicate that PQQ is a growth factor for certain bacteria under certain conditions. Despite the relatively high redox potential of the PQQ/PQQH₂ couple, quinoproteins transfer electrons to a variety of natural electron acceptors. Depending on the type of quinoprotein enzyme, the following components of the respiratory chain appear to be active: cytochrome c (sometimes with a copper protein as an intermediate), cytochrome b , and NADH dehydrogenase. PQQ is not restricted to a particular group of organisms, and reactions catalysed by quinoproteins can also be performed by NAD(P)-dependent or flavoprotein enzymes. Thus, these observations do not provide arguments for the view that quinoproteins have a unique role in microbial oxidations. Further comparative studies on oxidoreductases are necessary to reveal the special features of this novel group of enzymes.     

Failure to verify the presence of pyrroloquinoline quinone (PQQ) in bovine plasma amine oxidase by gas chromatography/mass spectrometry

The presence of covalently bound pyrroloquinoline quinone (PQQ) in bovine plasma amine oxidase (BPAO) was examined by the use of gas chromatography/mass spectrometry. The enzyme was subjected to proteolysis with proteinase in the presence of [U-13C]PQQ as an internal standard. After isolation and derivatization of PQQ with phenyltrimethylammonium hydroxide, molecular peaks at m/z 448 and 462 were used for detection of PQQ and [U-13C]PQQ, respectively, by selected ion monitoring (SIM). In the SIM profile, although the sample extract obtained from BPAO treated with proteinase clearly showed the peak at m/z 462 for the internal standard, there were no peaks detectable at m/z 448, showing the absence of PQQ in the proteolysis digest of BPAO. Thus, our results do not support the claim that BPAO contains covalently bound PQQ in its structure.     

Mutants ofMethylobacterium organophilum unable to synthesize PQQ

The phenotype of mutants unable to synthesize PQQ is analyzed for different categories of methylotrophic bacteria. The advantages offered by strains dissimilating methylamine through methylated amino-acids are discussed. InM.organophilum, 40% of the mutants unable to grow in methanol medium but with normal methylamine utilization, were affected in PQQ metabolism. The genetic properties ofM.organophilum useful to study PQQ mutants are discussed, mainly the use of pSUP106 to create insertion mutations in the bacterial chromosome and to replace wild-type genes by modified genes. An example is given of the possibility to create R plasmids containing large fragments ofM.organophilum DNA. Some physiological properties of a PQQ mutant are described, regarding growth kinetics, PQQ uptake and accumulation.     

The role of PQQ and quinoproteins in methylotrophic bacteria

Abstract Quinoprotein dehydrogenases play a non-exclusive role in the dissimilation of C₁ compounds. Methanol and methylamine oxidation occur by covalent catalysis while the reduction equivalents are transferred to the respiratory chain in one-electron steps. Cytochrome c _L is an excellent electron acceptor for methanol dehydrogenase at pH 7.0 and a bad one at pH 9.0. Efficient methanol oxidation (with NH₃ as activator) occurs at pH 9.0, but (due to the failure of NH₃) not at pH 7.0. Since stimulation occurred at the latter condition with a compound prepared from Hyphomicrobium X, most probably methanol oxidation in vivo requires the presence of a natural activator. The finding of pro-PQQ in methylamine dehydrogenase implicates that certain quinoproteins may have a modified tyrosine as cofactor. This type of quinoprotein is involved in assimilation routes which also occur in methylotrophs. l -Tyrosine and l -glutamate are the precursors of PQQ biosynthesis. Free intermediates in the route of biosynthesis have not been found. Most probably the whole process occurs on a protein matrix. In view of the significant amounts found in their culture fluid, methylotrophic bacteria seem particularly well suited for the fermentative production of PQQ.     

Utilization of an Escherichia coli mutant for carbon-13 enrichment of tRNA for NMR studies.

The enrichment of tRNA at specific sites with carbon-13 has been accomplished in vivo using a mutant of Escherichia coli. A relaxed strain of E. coli auxotrophic for methionine was grown in a specifically defined medium supplemented with either [14C] or [13C]-methyl labeled methionine. Cells were collected at the end of the log-phase of growth and tRNA was extracted. Analysis of the radioactivity of the [14C]-labeled tRNA established an incorporation ratio of three labeled carbons per tRNA molecule. Incorporation of the [14C]-label in vivo was confined to the methylation of nucleotides as determined by thin layer chromatography of nucleotides resulting from a ribonuclease digestion of [14C]-labeled tRNA. The carbon-13 NMR spectrum of [13C]-enriched tRNA indicated a similar degree of incorporation into the methylated nucleotides by the substantial enhancement of [13C]-methyl NMR signals only. Assignment of signals has been made for the methyl groups of ribothymidine and N7-methylguanosine in E. coli tRNA.     

Intestinal absorption and tissue distribution of [14C]pyrroloquinoline quinone in mice.

Pyrroloquinoline quinone (PQQ) functions as a cofactor for prokaryotic oxidoreductases, such as methanol dehydrogenase and membrane-bound glucose dehydrogenase. In animals fed chemically defined diets, PQQ improves reproductive outcome and neonatal growth. Consequently, the present study was undertaken to determine the extent to which PQQ is absorbed by the intestine, its tissue distribution, and route of excretion. About 28 micrograms of PQQ (0.42 microCi/mumol), labeled with 14C derived from L-tyrosine, was administered orally to Swiss-Webster mice (18-20 g) to estimate absorption. PQQ was readily absorbed (62%, range 19-89%) in the lower intestine, and was excreted by the kidneys (81% of the absorbed dose) within 24 hr. The only tissues that retained significant amounts of [14C]PQQ at 24 hr were skin and kidney. For kidney, it was assumed that retention of [14C]PQQ represented primarily PQQ destined for excretion. For skin, the concentration of [14C]PQQ increased from 0.3% of the absorbed dose at 6 hr to 1.3% at 24 hr. Furthermore, most of the [14C]PQQ in blood (greater than 95%) was associated with the blood cell fraction, rather than plasma.     

吡咯喹啉醌产生菌筛选方法建立及菌种筛选

吡咯喹啉醌(PQQ)是一种氧化还原酶的辅酶,具有多种生理功能。扩增得到大肠杆菌葡萄糖脱氢酶(GDH)基因,并利用表达载体pET28a在E.coli BL21(DE3)中进行了表达。纯化了可溶性表达产物,并建立了基于GDH的重组酶法分析PQQ的方法。确定了甲基营养菌筛选模型,从2000余份土样中分离得到一株PQQ高产生菌MP606,在未经培养条件优化及诱变选育的条件下PQQ产量达113mg/L。从该菌培养液中制备得到了产物的结晶,HPLC分析、特征光谱分析以及酶法分析均证实该产物为PQQ。扩增并分析了MP606的16S rDNA序列,结果显示该菌16S rDNA序列与12种甲基营养菌都具有95%以上同源性,其中与食甲基菌属两菌株的16S rDNA序列同源性达99%。     

Novel and efficient screening of PQQ high-yielding strains and subsequent cultivation optimization

A novel and efficient screening method for pyrroloquinoline quinone (PQQ) high-yielding methylotrophic strains was developed by using glucose dehydrogenase apoenzyme (GDHA) which depended on PQQ as the cofactor. Using this high-throughput method, PQQ high-yielding strains were rapidly screened out from thousands of methylotrophic colonies at a time. The comprehensive phylogenetic analysis revealed that the highest PQQ-producing strain zju323 (CCTCC M 2016079) could be assigned to a novel species in the genus Methylobacillus of the Betaproteobacteria. After systematic optimization of different medium components and cultivation conditions, about 33.4 mg/L of PQQ was obtained after 48 h of cultivation with Methylobacillus sp. zju323 at the shake flask scale. Further cultivations of Methylobacillus sp. zju323 were carried out to investigate the biosynthesis of PQQ in 10-L bench-top fermenters. In the batch operation, the PQQ accumulation reached 78 mg/L in the broth after 53 h of cultivation. By adopting methanol feeding strategy, the highest PQQ concentration was improved up to 162.2 mg/L after 75 h of cultivation. This work developed a high-throughput strategy of screening PQQ-producing strains from soil samples and also demonstrated one potential bioprocess for large-scale PQQ production with the isolated PQQ strain.     

A 13C NMR study of [5,8-13C2]spermidine binding to tRNA and to Escherichia coli macromolecules

[5,8-13C2]Spermidine was prepared by synthesis, and its binding to macromolecular structures of Escherichia coli was studied. When added to E. coli cells, the two signals of [13C]spermidine (C-5, 47.8 ppm, and C-8, 39.6 ppm; JC-C = 5.8 Hz) were strongly broadened due to binding to macromolecules. When [13C]spermidine was added to E. coli tRNA, the C-5 resonance broadened to v1/2 = 4.7 Hz, whereas the C-8 resonance broadened to v1/2 = 2.7 Hz. tRNA-bound [13C]spermidine could be chased by [12C]spermidine or spermine, but not by putrescine or cadaverine. By using mixtures of [5-13C]- and [8-13C]spermidines (where 13C-13C coupling was avoided), it was possible to estimate a dissociation constant (Kd) of 3 x 10(-3) M using the C-5 v1/2obs values and a Kd of 2.10(-3) M using the C-8 v1/2obs values. The number of spermidine-binding sites (n) could also be estimated by fitting the bound spermidine molar fraction versus tRNA concentration. Values of n = 12 +/- 2 and 14 +/- 3 were obtained for C-5 and C-8, respectively. Measurements of line narrowing at increasing Mg2+ concentrations indicated that approximately 11 spermidines (of the 12-14 bound ones) could be displaced by the former, whereas 3 spermidines remain strongly bound to the tRNA backbone. Measurements of free and bound T1 allowed the determination of a correlation time of 10(-10)s for tRNA-bound spermidine.     

On the biosynthesis of free and covalently bound PQQ. Glutamic acid decarboxylase from Escherichia coli is a pyridoxo-quinoprotein

Analysis of glutamic acid decarboxylase (GDC) (EC 4.1.1.15) from Escherichia coli ATCC 11246 revealed the presence of six pyridoxal phosphates (PLPs) as well as six covalently bound pyrroloquinoline quinones (PQQs) per hexameric enzyme molecule. This is the second example of a pyridoxo-quinoprotein, suggesting that other atypical pyridoxoproteins (PLP-containing enzymes) have similar cofactor composition. Since the organism did not produce free PQQ and its quinoprotein glucose dehydrogenase was present in the apo form, free PQQ is not used in the assemblage of GDC. Most probably, biosynthesis of covalently bound cofactor occurs in situ via a route which is different from that of free PQQ. Thus, organisms previously believed to be unable to synthesize (free) PQQ could in fact be able to produce quinoproteins with covalently bound cofactor. Implications for the role of PQQ in eukaryotic cells are discussed.     

Properties of a D-glutamic acid-requiring mutant of Escherichia coli

Some properties of a d-glutamic acid auxotroph of Escherichia coli B were studied. The mutant cells lysed in the absence of d-glutamic acid. Murein synthesis was impaired, accompanied by accumulation of uridine-5'-diphosphate-N-acetyl-muramyl-l-alanine (UDP-MurNac-l-Ala), as was shown by incubation of the mutant cells in a cell wall medium containing l-[(14)C]alanine. After incubation of the parental strain in a cell wall medium containing l-[(14)C]glutamic acid, the acid-precipitable radioactivity was lysozyme degradable to a large extent. Radioactive UDP-MurNac-pentapeptide was isolated from the l-[(14)C]glutamic acid-labeled parental cells. After hydrolysis, the label was exclusively present in glutamic acid, the majority of which had the stereo-isomeric d-configuration. Compared to the parent the mutant incorporated less l-[(14)C]glutamic acid from the wall medium into acid-precipitable material. Lysozyme degraded a smaller percentage of the acid-precipitable material of the mutant than of that of the parent. No radioactive uridine nucleotide precursors could be isolated from the mutant under these conditions. Attempts to identify the enzymatic defect in this mutant were not successful. The activity of UDP-MurNac-l-Ala:d-glutamic acid ligase (ADP; EC 6.3.2.9) (d-glutamic acid adding enzyme) is not affected by the mutation. Possible pathways for d-glutamic acid biosynthesis in E. coli B are discussed.     

Dietary pyrroloquinoline quinone (PQQ) alters indicators of inflammation and mitochondrial-related metabolism in human subjects

Pyrroloquinoline quinone (PQQ) influences energy-related metabolism and neurologic functions in animals. The mechanism of action involves interactions with cell signaling pathways and mitochondrial function. However, little is known about the response to PQQ in humans. Using a crossover study design, 10 subjects (5 females, 5 males) ingested PQQ added to a fruit-flavored drink in two separate studies. In study 1, PQQ was given in a single dose (0.2 mg PQQ/kg). Multiple measurements of plasma and urine PQQ levels and changes in antioxidant potential [based on total peroxyl radical-trapping potential and thiobarbituric acid reactive product (TBAR) assays] were made throughout the period of 48 h. In study 2, PQQ was administered as a daily dose (0.3 mg PQQ/kg). After 76 h, measurements included indices of inflammation [plasma C-reactive protein, interleukin (IL)-6 levels], standard clinical indices (e.g., cholesterol, glucose, high-density lipoprotein, low-density lipoprotein, triglycerides, etc.) and ¹H-nuclear magnetic resonance estimates of urinary metabolites related in part to oxidative metabolism. The standard clinical indices were normal and not altered by PQQ supplementation. However, dietary PQQ exposure (Study 1) resulted in apparent changes in antioxidant potential based on malonaldehyde-related TBAR assessments. In Study 2, PQQ supplementation resulted in significant decreases in the levels of plasma C-reactive protein, IL-6 and urinary methylated amines such as trimethylamine N-oxide, and changes in urinary metabolites consistent with enhanced mitochondria-related functions. The data are among the first to link systemic effects of PQQ in animals to corresponding effects in humans.     

Pyrroloquinoline quinone (coenzyme PQQ) and the oxidation of SH residues in proteins.

Pyrroloquinoline quinone (PQQ) catalyzes the oxidation of cysteamine at neutral pH with a second order rate constant K2 = 0.45 M-1 s-1. The reduction of PQQ was monitored by absorption and fluorescence spectroscopy, whereas the oxidation of cysteamine to cystamine was followed by titration with 5,5'-dithiobis(2-nitrobenzoic acid). PQQ also catalyzes the oxidation of thiol groups critically connected with the function of two proteins, i.e. thioredoxin and phosphoribulose kinase. The reaction of PQQ with reduced thioredoxin brings about the oxidation of two thiol groups of the oxireductase, whereas the enzyme phosphoribulose kinase is inactivated at 25 degrees C. The oxidized disulfide bond of phosphoribulose kinase is reduced by dithiothreitol and the enzyme recovers catalytic activity. The ability of PQQ to catalyze the oxidation of vicinal cysteinyl residues to generate disulfide bonds under mild experimental conditions can be exploited to define the precise role of modified thiol residues in either catalysis or stabilization of protein structure.