The origin of sulfur in biotin

The comparative ability of Escherichia coli K-12 hpb lambda-, a biotin overproducing strain, to incorporate 35S from isotopically labeled L-methionine, L-cystine, and the sulfane sulfur of thiocystine was determined. Comparison of the specific activity of sulfur in biotin produced by the organism with that of the 35S-labeled amino acids demonstrates that the sulfur of cystine is transferred to biotin with an efficiency of at least 75%, that the sulfur of methionine does not contribute to biotin significantly, and that the sulfane sulfur of thiocystine contributes approximately one-third of the sulfur to newly synthesized biotin and is essentially equivalent in utilization to that of the other two sulfur atoms in the molecule.     

The enzymology of sulfur activation during thiamin and biotin biosynthesis.

The thiamin and biotin biosynthetic pathways utilize elaborate strategies for the transfer of sulfur from cysteine to cofactor precursors. For thiamin, the sulfur atom of cysteine is transferred to a 66-amino-acid peptide (ThiS) to form a carboxy-terminal thiocarboxylate group. This sulfur transfer requires three enzymes and proceeds via a ThiS-acyladenylate intermediate. The biotin synthase Fe-S cluster functions as the immediate sulfur donor for biotin formation. C-S bond formation proceeds via radical intermediates that are generated by hydrogen atom transfer from dethiobiotin to the adenosyl radical. This radical is formed by the reductive cleavage of S-adenosylmethionine by the reduced Fe-S cluster of biotin synthase.     

Uptake of extracellular biotin by Escherichia coli biotin prototrophs.

Uptake of exogenous biotin by two Escherichia coli biotin prototroph strains, K-12 and Crookes, appeared to involve incorporation at a fixed number of binding sites located at the cell membrane. Incorporation was characterized as a binding process specific for biotin, not requiring energy, and stimulated by acidic pH. Constant saturation quantities of exogenous biotin were incorporated by these cells, and the amounts, which were titrated, depended on whether the cells were resting or dividing. Resting cells incorporated exogenous biotin amounting to 2% of their total intracellular biotin content. Fifty percent of the exogenous biotin was incorporated into their free biotin fraction, and 50% was incorporated into their bound biotin fraction. On the other hand, dividing cells incorporated exogenous biotin into all of their intracellular sites, 88% going into the intracellular-bound biotin fraction, and 12% going into the free biotin fraction. Calculations suggested that each cell contained approximately 3,000 binding sites for biotin. It was postulated that biotin incorporation sites might have been components of acetyl coenzyme A carboxylase located at or near the membrane.     

Overexpression of biotin synthase and biotin ligase is required for efficient generation of sulfur-35 labeled biotin in <Emphasis Type="Italic">E. coli</Emphasis>

Background  

Biotin is an essential enzyme cofactor that acts as a CO₂ carrier in carboxylation and decarboxylation reactions. The E. coli genome encodes a biosynthetic pathway that produces biotin from pimeloyl-CoA in four enzymatic steps. The final step, insertion of sulfur into desthiobiotin to form biotin, is catalyzed by the biotin synthase, BioB. A dedicated biotin ligase (BirA) catalyzes the covalent attachment of biotin to biotin-dependent enzymes. Isotopic labeling has been a valuable tool for probing the details of the biosynthetic process and assaying the activity of biotin-dependent enzymes, however there is currently no established method for ³⁵S labeling of biotin.     

Structure-function studies of Escherichia coli biotin synthase via a chemical modification and site-directed mutagenesis approach.

In Escherichia coli, biotin synthase (bioB gene product) catalyzes the key step in the biotin biosynthetic pathway, converting dethiobiotin (DTB) to biotin. Previous studies have demonstrated that BioB is a homodimer and that each monomer contains an iron-sulfur cluster. The purified BioB protein, however, does not catalyze the formation of biotin in a conventional fashion. The sulfur atom in the iron-sulfur cluster or from the cysteine residues in BioB have been suggested to act as the sulfur donor to form the biotin molecule, and yet unidentified factors were also proposed to be required to regenerate the active enzyme. In order to understand the catalytic mechanism of BioB, we employed an approach involving chemical modification and site-directed mutagenesis. The properties of the modified and mutated BioB species were examined, including DTB binding capability, biotin converting activity, and Fe(2+) content. From our studies, four cysteine residues (Cys 53, 57, 60, and 97) were assigned as the ligands of the iron-sulfur cluster, and Cys to Ala mutations completely abolished biotin formation activity. Two other cysteine residues (Cys 128 and 188) were found to be involved mainly in DTB binding. The tryptophan and histidine residues were suggested to be involved in DTB binding and dimer formation, respectively. The present study also reveals that the iron-sulfur cluster with its ligands are the key components in the formation of the DTB binding site. Based on the current results, a refined model for the reaction mechanism of biotin synthase is proposed.     

Enzyme-mediated sulfide production for the reconstitution of [2Fe-2S] clusters into apo-biotin synthase of Escherichia coli. Sulfide transfer from cysteine to biotin.

We previously showed that biotin synthase in which the (Fe-S) cluster was labelled with 34S by reconstitution donates 34S to biotin [B. Tse Sum Bui, D. Florentin, F. Fournier, O. Ploux, A. Méjean & A. Marquet (1998) FEBS Lett. 440, 226-230]. We therefore proposed that the source of sulfur was very likely the (Fe-S) centre. This depletion of sulfur from the cluster during enzymatic reaction could explain the absence of turnover of the enzyme which means that to restore a catalytic activity, the clusters have to be regenerated. In this report, we show that the NifS protein from Azotobacter vinelandii and C-DES from Synechocystis as well as rhodanese from bovine liver can mobilize the sulfur, respectively, from cysteine and thiosulfate for the formation of a [2Fe-2S] cluster in the apoprotein of Escherichia coli biotin synthase. The reconstituted enzymes were as active as the native enzyme. When [35S]cysteine was used during the reconstitution experiments in the presence of NifS, labelled (Fe35S) biotin synthase was obtained. This enzyme produced [35S]biotin, confirming the results obtained with the 34S-reconstituted enzyme. NifS was also effective in mobilizing selenium from selenocystine to produce an (Fe-Se) cluster. However, though NifS could efficiently reconstitute holobiotin synthase from the apoform, starting from cysteine, these two effectors had no significant effect on the turnover of the enzyme in the in vitro assay.     

Spectroscopic changes during a single turnover of biotin synthase: destruction of a [2Fe-2S] cluster accompanies sulfur insertion.

Biotin synthase catalyzes the insertion of a sulfur atom between the saturated C6 and C9 carbons of dethiobiotin. Catalysis requires AdoMet and flavodoxin and generates 5'-deoxyadenosine and methionine, suggesting that biotin synthase is an AdoMet-dependent radical enzyme. Biotin synthase (BioB) is aerobically purified as a dimer of 38.4 kDa monomers that contains 1-1.5 [2Fe-2S](2+) clusters per monomer and can be reconstituted with exogenous iron, sulfide, and reductants to contain up to two [4Fe-4S] clusters per monomer. The iron-sulfur clusters may play a dual role in biotin synthase: a reduced iron-sulfur cluster is probably involved in radical generation by mediating the reductive cleavage of AdoMet, while recent in vitro labeling studies suggest that an iron-sulfur cluster also serves as the immediate source of sulfur for the biotin thioether ring. Consistent with this dual role for iron-sulfur clusters in biotin synthase, we have found that the protein is stable, containing one [2Fe-2S](2+) cluster and one [4Fe-4S](2+) cluster per monomer. In the present study, we demonstrate that this mixed cluster state is essential for optimal activity. We follow changes in the Fe and S content and UV/visible and EPR spectra of the enzyme during a single turnover and conclude that during catalysis the [4Fe-4S](2+) cluster is preserved while the [2Fe-2S](2+) cluster is destroyed. We propose a mechanism for incorporation of sulfur into dethiobiotin in which a sulfur atom is oxidatively extracted from the [2Fe-2S](2+) cluster.     

Biochemical characterization of the Arabidopsis biotin synthase reaction. The importance of mitochondria in biotin synthesis.

Biotin synthase, encoded by the bio2 gene in Arabidopsis, catalyzes the final step in the biotin biosynthetic pathway. The development of radiochemical and biological detection methods allowed the first detection and accurate quantification of a plant biotin synthase activity, using protein extracts from bacteria overexpressing the Arabidopsis Bio2 protein. Under optimized conditions, the turnover number of the reaction was >2 h(-1) with this in vitro system. Purified Bio2 protein was not efficient by itself in supporting biotin synthesis. However, heterologous interactions between the plant Bio2 protein and bacterial accessory proteins yielded a functional biotin synthase complex. Biotin synthase in this heterologous system obeyed Michaelis-Menten kinetics with respect to dethiobiotin (K(m) = 30 microM) and exhibited a kinetic cooperativity with respect to S-adenosyl-methionine (Hill coefficient = 1.9; K(0.5) = 39 microM), an obligatory cofactor of the reaction. In vitro inhibition of biotin synthase activity by acidomycin, a structural analog of biotin, showed that biotin synthase reaction was the specific target of this inhibitor of biotin synthesis. It is important that combination experiments using purified Bio2 protein and extracts from pea (Pisum sativum) leaf or potato (Solanum tuberosum) organelles showed that only mitochondrial fractions could elicit biotin formation in the plant-reconstituted system. Our data demonstrated that one or more unidentified factors from mitochondrial matrix (pea and potato) and from mitochondrial membranes (pea), in addition to the Bio2 protein, are obligatory for the conversion of dethiobiotin to biotin, highlighting the importance of mitochondria in plant biotin synthesis.     

Metabolism of biotin and analogues of biotin by microorganisms. IV. Degradation of biotin, oxybiotin, and desthiobiotin by Lactobacillus casei

Birnbaum, Jerome (University of Cincinnati, Cincinnati, Ohio), and Herman C. Lichstein. Metabolism of biotin and analogues of biotin by microorganisms. IV. Degradation of biotin, oxybiotin, and desthiobiotin by Lactobacillus casei. J. Bacteriol. 92:925-930. 1966.-Lactobacillus casei degrades biotin when it is present in excess to products not utilizable for growth by L. plantarum or Saccharomyces cerevisiae. Degrading activity was initiated in the early stationary phase and was controlled by the pH of the medium. Nonproliferating cells, grown previously in excess biotin for 40 hr, metabolized oxybiotin and desthiobiotin as well as biotin. Cells grown in low biotin, or in excess biotin for 20 hr, did not degrade either analogue. Oxybiotin was 50% as active as biotin for growth, whereas desthiobiotin acted as a competitive inhibitor. Cells grown in excess biotin for 40 hr, but not 20 hr, overcame the inhibitory effect of desthiobiotin, when subcultured to media containing a normally inhibitory concentration of the analogue. Moreover, the level of desthiobiotin dropped rapidly during the first 4 to 6 hr before growth ensued. The data indicate that growth in excess biotin enables L. casei to degrade desthiobiotin and, thereby, to overcome the inhibitory effect of the analogue.     

Studies on the biosynthesis of biotin. Production of biotin and biotin-like compounds by a pseudomonad

1. Filtrates from cultures of a strain of Pseudomonas aeruginosa, grown in a basal glucose-ammonium chloride-vitamins-salts medium, possessed biotin activity as detected by microbiological assays. Exponential-phase culture filtrates contained biotin and desthiobiotin in the approximate ratio 1:3, with smaller amounts of biotin sulphoxide and three unidentified compounds with biotin activity. 2. The addition of malonate, adipate or pimelate to the basal medium stimulated the production of compounds with biotin activity; this effect was enhanced when these compounds were included in the medium as the major carbon source. Succinate, glutarate, suberate, fumarate or oxaloacetate did not stimulate the production of compounds with biotin activity. The ratio of biotin to desthiobiotin in filtrates from cultures grown in medium containing malonate as the carbon source was about 1:1. Experiments in which mixtures of malonate and pimelate were included in the medium as the carbon sources showed that these acids probably make a similar contribution in biotin biosynthesis. 3. A number of heterocyclic compounds, including several containing the ureido group (-NH-CO-NH-), were included in the basal medium but none of them stimulated the production of compounds with biotin activity to any marked degree. 4. Several amino acids, particularly cysteine (or cystine) and lysine, when added individually as supplements to the basal medium, stimulated the production of compounds with biotin activity. Filtrates from cultures grown in medium supplemented with cysteine contained approximately equal proportions of biotin and desthiobiotin. A much greater stimulation in the production of compounds with biotin activity was obtained when certain amino acids were included in the medium as the major source of nitrogen or carbon and nitrogen; ornithine, citrulline and argininosuccinate had the most marked effect. The ratio of biotin to desthiobiotin in filtrates from these cultures was usually greater than in filtrates from cultures grown in basal medium. 5-Aminovalerate also caused some stimulation when used as the nitrogen source, but urea was inactive. The effect of binary mixtures of certain amino acids was also examined. 5. The results are discussed in relation to the possible role of the stimulatory compounds during biotin biosynthesis.     

Enzymatic determination of biotin.

An enzymatic method for the quantitative determination of biotin has been developed. The method involves the enzymatic binding of biotin in situ to the pyruvate carboxylase apoprotein of biotin-deficient bakers' yeast and the subsequent estimation of the pyruvate carboxylase activity by a ¹⁴CO₂-fixation method. The method is specific for biotin. Several biotin analogs and precursors were tested, and only biocytin was found to interfere, Biotin amounts of less than 5 pg can be estimated.     

Effect of biotin on ribonucleic acid synthesis.

A single injection of biotin to biotin-deficient rats produces a two-fold increase in the incorporation, both in vivo and in vitro of precursors into nucleic acids as early as 2 h after the biotin treatment. The specific activity of the precursor pool is not affected by biotin. Analysis of the polysome profile at various times following biotin treatment and a kinetic study of the effect of excess poly(U) on the incorporation of phenylalanine by cell-free amino acid incorporation experiments indicate a marked decrease in messenger-free ribosomes in rat liver after biotin administration.     

Production of antibodies that bind biotin and inhibit biotin containing enzymes.

Methods were developed for the coupling of biotin to bovine serum albumin and bovine gamma-globulin using a water-soluble carbodimide. The use of [14-C]biotin as a tracer allowed quantitation of the incorporation of biotin into the conjugates: 2.55 mol of biotin was incorporated per mol of gamma-globulin and 7-9 mol of biotin was incorporated per mol of serum albumin in different preparations. These conjugates were highly immunogenic in the rabbit and anti-bodies reactive with the biotinyl group itself could be detected by their ability to precipitate the heterologous biotinated carrier but not the unmodified heterologous carrier. There antisera rapidly inactivated transcarboxylase and pyruvate carboxylase and this inactivation could be blocked by pretreatment of the antisera with biotin or biocytin. Using enzyme inhibition to detect free antibody, the binding constant for biotin was found to be 5.0 x 10- minus 8 M and that for biocytin 3.5 x 10- minus 8 M.     

Incorporation of the sulfur of L-[35S]methionine into the biotin molecule by intact cells of Rhodotorula glutinis

The source of sulfur for biotin in microorganisms was studied. Using intact cells of Rhodotorula glutinis AKU 4847, L-methionine was much more effective for the synthesis of biotin from dethiobiotin than various other sulfur compounds tested. The reaction was carried out in the presence of L-[³⁵S]methionine. The radioactive biotin synthesized was isolated from the reaction mixture by a procedure involving cation- and anion-exchange column chromatographies, avidin treatment and membrane filtration, and then identified by radiochromatography and bioautography with Lactobacillus arabinosus. It was thus shown that the sulfur of methionine was incorporated into the biotin molecule by R. glutinis.     

The novel structure and chemistry of iron-sulfur clusters in the adenosylmethionine-dependent radical enzyme biotin synthase

Biotin synthase is an adenosylmethionine-dependent radical enzyme that catalyzes the substitution of sulfur for hydrogen at the saturated C6 and C9 positions in dethiobiotin. The structure of the biotin synthase monomer is an (alpha/beta)(8) barrel that contains one [4Fe-4S](2+) cluster and one [2Fe-2S](2+) cluster that encapsulate the substrates AdoMet and dethiobiotin. The air-sensitive [4Fe-4S](2+) cluster and the reductant-sensitive [2Fe-2S](2+) cluster have unique coordination environments that include close proximity to AdoMet and DTB, respectively. The relative positioning of these components, as well as several conserved protein residues, suggests at least two potential catalytic mechanisms that incorporate sulfur from either the [2Fe-2S](2+) cluster or a cysteine persulfide into the biotin thiophane ring. This review summarizes an accumulating consensus regarding the physical and spectroscopic properties of each FeS cluster, and discusses possible roles for the [4Fe-4S](2+) cluster in radical generation and the [2Fe-2S](2+) cluster in sulfur incorporation.     

Incorporation of the sulfur of L-[S]methionine into the biotin molecule by intact cells of Rhodotorula glutinis

The source of sulfur for biotin in microorganisms was studied. Using intact cells of Rhodotorula glutinis AKU 4847, L-methionine was much more effective for the synthesis of biotin from dethiobiotin than various other sulfur compounds tested. The reaction was carried out in the presence of L-[³⁵S]methionine. The radioactive biotin synthesized was isolated from the reaction mixture by a procedure involving cation- and anion-exchange column chromatographies, avidin treatment and membrane filtration, and then identified by radiochromatography and bioautography with Lactobacillus arabinosus. It was thus shown that the sulfur of methionine was incorporated into the biotin molecule by R. glutinis.     

Metabolism of biotin and analogues of biotin by microorganisms. II. Further studies on the conversion of D-biotin to biotin vitamers by Lactobacillus plantarum

Birnbaum, Jerome (University of Cincinnati, Cinncinati, Ohio), and Herman C. Lichstein. Metabolism of biotin and analogues of biotin by microorganisms. II. Further studies on the conversion of d-biotin to biotin vitamers by Lactobacillus plantarum. J. Bacteriol. 92:913-919. 1966.-Lactobacillus plantarum growing in excess biotin converts a portion to two vitamers (combinable and uncombinable with avidin) not utilizable for growth. These were detected by differential yeast-lactobacillus assay. In the present study, suspensions of 12- and 72-hr cells showed no converting activity. Vitamer formation by nonproliferating 24-hr cells required glucose and exhibited a lag; 17-hr cells showed neither a lag nor a glucose requirement. Iodoacetate and chloramphenicol inhibited vitamer formation by 24-hr cells, but had no effect on 17-hr cells. Addition of hydrolyzed casein or preincubation in biotin decreased the lag and enhanced vitamer formation in 24-hr cells, but had no effect in 17-hr cells. Apparently, 17-hr cells contain the converting enzymes which degenerate as growth proceeds; the lag exhibited by 24-hr cells represents the time necessary to reform the enzymes. Equal amounts of the two vitamers were formed in 17-hr cells; only the avidin-combinable form was produced initially by 24-hr cells, unless hydrolyzed casein was present. Electrophoresis revealed that the avidin-combinable vitamer has the same charge as biotin,whereas the uncombinable form possesses both positive and negative groups. Column chromatography was used to separate the avidin uncombinable material from biotin and the avidin-combinable form. L. plantarum was unable to accumulate the avidin-uncombinable vitamer under conditions permitting good biotin accumulation. It was concluded that L. plantarum sequentially converts biotin to avidin-combinable and -uncombinable vitamers, the latter being impermeable to the cells.     

Determination of the metabolic origins of the sulfur and 3'-nitrogen atoms in biotin of Escherichia coli by mass spectrometry

Two steps in the biosynthesis of biotin in Escherichia coli, incorporation of the nitrogen atom of methionine into 7-keto-8-aminopelargonic acid and of the sulfur atom into dethiobiotin, were examined. Sulfur and nitrogen metabolism were monitored by gas chromatography-mass spectrometry of volatile derivatives of internal (protein-bound) amino acids and excreted biotin. We were able to show that internal cysteine and excreted biotin were labeled to the same extent with 34S from either of two exogenous sulfur sources, 34SO4(2)-or L-[sulfane-34S]thiocystine. Internal methionine was eliminated from consideration, while cysteine, or possibly a closely related intermediate, was implicated as providing the sulfur atom for biotin biosynthesis. Also, in experiments designed to follow the metabolism of the nitrogen atom of methionine, it was found that biotin excreted into the culture medium by this organism grown with 95 atom % [15N]methionine contained greater than 70 atom % excess 15N in one of the nitrogens over that obtained from cultures grown with methionine of natural abundance 15N. These results provide evidence for the direct transfer of the methionine nitrogen as the role of S-adenosylmethionine in the conversion of 7-keto-8-aminopelargonic acid to 7,8-diaminopelargonic acid.     

Acute glucocorticoid treatment increases urinary biotin excretion and serum biotin

Previous studies have demonstrated that glucocorticoids alter biotin metabolism. To extend these studies, the effect of dexamethasone on biotin pools was analyzed in rats consuming a purified diet containing a more physiological level of dietary biotin intake (0.06 mg/kg). Acute (5 h) dexamethasone administration (0.5 mg/kg) elicited elevated urinary glucose output as well as elevated urinary biotin excretion and serum biotin. Renal and hepatic free biotin was also significantly elevated by acute dexamethasone administration. Chow-fed rats treated with an acute administration of dexamethasone demonstrated significantly elevated urinary glucose excretion, urinary biotin excretion, and serum biotin, but no change in tissue associated biotin was detected. Chronic administration of dexamethasone (0.5 mg/kg ip) over 4 days significantly elevated urinary glucose excretion 42% but had no effect on urinary biotin excretion, serum biotin, or hepatic- or renal-associated free biotin. These results demonstrate the existence of potentially novel regulatory pathways for total biotin pools and the possibility that experimental models with high initial biotin status may mask potentially important regulatory mechanisms.     

Metabolism of biotin and analogues of biotin by microorganisms. 3. Degradation of oxybiotin and desthiobiotin by Lactobacillus plantarum

Birnbaum, Jerome (University of Cincinnati, Cincinnati, Ohio), and Herman C. Lichstein. Metabolism of biotin and analogues of biotin by microorganisms. III. Degradation of oxybiotin and desthiobiotin by Lactobacillus plantarum. J. Bacteriol 92:920-924. 1966.-Lactobacillus plantarum growing in excess oxybiotin degraded a portion to products not utilizable by Saccharomyces cerevisiae. The loss of activity for the yeast suggested that no vitamers of oxybiotin accumulated during the degradation. The initiation of degrading activity was controlled by the pH of the growth medium and appeared during early stationary phase. Only cells grown in excess oxybiotin could degrade this biotin analogue. Nonproliferating cells grown previously in excess oxybiotin were able to convert biotin to vitamers (active for the yeast) as well as to degrade oxybiotin. Those grown in excess biotin also developed the ability to degrade oxybiotin as well as to convert biotin; however, in this case, the enzymes degenerated more rapidly. Cells grown with excessive amounts of either material were able to degrade desthiobiotin to products not available for the yeast. Both biotin conversion and oxybiotin degradation were found to have the same requirements for Mg and Mn ions. It was concluded that conversion of biotin to vitamers, and the degradation of oxybiotin or desthiobiotin are functions of the same on closely related enzyme systems.