The origin of sulfur in biotin

Biotin Synthesis in Ralstonia eutropha H16 Utilizes Pimeloyl Coenzyme A and Can Be Regulated by the Amount of Acceptor Protein

The biotin metabolism of the Gram-negative facultative chemolithoautotrophic bacterium Ralstonia eutropha (syn. Cupriavidus necator), which is used for biopolymer production in industry, was investigated. A biotin auxotroph mutant lacking bioF was generated, and biotin depletion in the cells and the minimal biotin demand of a biotin-auxotrophic R. eutropha strain were determined. Three consecutive cultivations in biotin-free medium were necessary to prevent growth of the auxotrophic mutant, and 40 ng/ml biotin was sufficient to promote cell growth. Nevertheless, 200 ng/ml biotin was necessary to ensure growth comparable to that of the wild type, which is similar to the demand of biotin-auxotrophic mutants among other prokaryotic and eukaryotic microbes. A phenotypic complementation of the R. eutropha ΔbioF mutant was only achieved by homologous expression of bioF of R. eutropha or heterologous expression of bioF of Bacillus subtilis but not by bioF of Escherichia coli Together with the results from bioinformatic analysis of BioFs, this leads to the assumption that the intermediate of biotin synthesis in R. eutropha is pimeloyl-CoA instead of pimeloyl-acyl carrier protein (ACP) like in the Gram-positive B. subtilis Internal biotin content was enhanced by homologous expression of accB, whereas homologous expression of accB and accC2 in combination led to decreased biotin concentrations in the cells. Although a DNA-binding domain of the regulator protein BirA is missing, biotin synthesis seemed to be influenced by the amount of acceptor protein present.IMPORTANCERalstonia eutropha is applied in industry for the production of biopolymers and serves as a research platform for the production of diverse fine chemicals. Due to its ability to grow on hydrogen and carbon dioxide as the sole carbon and energy source, R. eutropha is often utilized for metabolic engineering to convert inexpensive resources into value-added products. The understanding of the metabolic pathways in this bacterium is mandatory for further bioengineering of the strain and for the development of new strategies for biotechnological production.

Biotin and Lipoic Acid: Synthesis, Attachment, and Regulation

Two vitamins, biotin and lipoic acid, are essential in all three domains of life. Both coenzymes function only when covalently attached to key metabolic enzymes. There they act as "swinging arms" that shuttle intermediates between two active sites (= covalent substrate channeling) of key metabolic enzymes. Although biotin was discovered over 100 years ago and lipoic acid 60 years ago, it was not known how either coenzyme is made until recently. In Escherichia coli the synthetic pathways for both coenzymes have now been worked out for the first time. The late steps of biotin synthesis, those involved in assembling the fused rings, were well described biochemically years ago, although recent progress has been made on the BioB reaction, the last step of the pathway in which the biotin sulfur moiety is inserted. In contrast, the early steps of biotin synthesis, assembly of the fatty acid-like "arm" of biotin were unknown. It has now been demonstrated that the arm is made by using disguised substrates to gain entry into the fatty acid synthesis pathway followed by removal of the disguise when the proper chain length is attained. The BioC methyltransferase is responsible for introducing the disguise, and the BioH esterase is responsible for its removal. In contrast to biotin, which is attached to its cognate proteins as a finished molecule, lipoic acid is assembled on its cognate proteins. An octanoyl moiety is transferred from the octanoyl acyl carrier protein of fatty acid synthesis to a specific lysine residue of a cognate protein by the LipB octanoyltransferase followed by sulfur insertion at carbons C-6 and C-8 by the LipA lipoyl synthetase. Assembly on the cognate proteins regulates the amount of lipoic acid synthesized, and, thus, there is no transcriptional control of the synthetic genes. In contrast, transcriptional control of the biotin synthetic genes is wielded by a remarkably sophisticated, yet simple, system, exerted through BirA, a dual-function protein that both represses biotin operon transcription and ligates biotin to its cognate proteins.

Biotin and Lipoic Acid: Synthesis, Attachment, and Regulation

Two vitamins, biotin and lipoic acid, are essential in all three domains of life. Both coenzymes function only when covalently attached to key metabolic enzymes. There they act as "swinging arms" that shuttle intermediates between two active sites (= covalent substrate channeling) of key metabolic enzymes. Although biotin was discovered over 100 years ago and lipoic acid was discovered 60 years ago, it was not known how either coenzyme is made until recently. In Escherichia coli the synthetic pathways for both coenzymes have now been worked out for the first time. The late steps of biotin synthesis, those involved in assembling the fused rings, were well described biochemically years ago, although recent progress has been made on the BioB reaction, the last step of the pathway, in which the biotin sulfur moiety is inserted. In contrast, the early steps of biotin synthesis, assembly of the fatty acid-like "arm" of biotin, were unknown. It has now been demonstrated that the arm is made by using disguised substrates to gain entry into the fatty acid synthesis pathway followed by removal of the disguise when the proper chain length is attained. The BioC methyltransferase is responsible for introducing the disguise and the BioH esterase for its removal. In contrast to biotin, which is attached to its cognate proteins as a finished molecule, lipoic acid is assembled on its cognate proteins. An octanoyl moiety is transferred from the octanoyl-ACP of fatty acid synthesis to a specific lysine residue of a cognate protein by the LipB octanoyl transferase, followed by sulfur insertion at carbons C6 and C8 by the LipA lipoyl synthetase. Assembly on the cognate proteins regulates the amount of lipoic acid synthesized, and thus there is no transcriptional control of the synthetic genes. In contrast, transcriptional control of the biotin synthetic genes is wielded by a remarkably sophisticated, yet simple, system exerted through BirA, a dual-function protein that both represses biotin operon transcription and ligates biotin to its cognate protein.

Biotin synthase: insights into radical-mediated carbon-sulfur bond formation

The enzyme cofactor and essential vitamin biotin is biosynthesized in bacteria, fungi, and plants through a pathway that culminates with the addition of a sulfur atom to generate the five-membered thiophane ring. The immediate precursor, dethiobiotin, has methylene and methyl groups at the C6 and C9 positions, respectively, and formation of a thioether bridging these carbon atoms requires cleavage of unactivated CH bonds. Biotin synthase is an S-adenosyl-l-methionine (SAM or AdoMet) radical enzyme that catalyzes reduction of the AdoMet sulfonium to produce 5'-deoxyadenosyl radicals, high-energy carbon radicals that can directly abstract hydrogen atoms from dethiobiotin. The available experimental and structural data suggest that a [2Fe-2S](2+) cluster bound deep within biotin synthase provides a sulfur atom that is added to dethiobiotin in a stepwise reaction, first at the C9 position to generate 9-mercaptodethiobiotin, and then at the C6 position to close the thiophane ring. The formation of sulfur-containing biomolecules through a radical reaction involving an iron-sulfur cluster is an unprecedented reaction in biochemistry; however, recent enzyme discoveries suggest that radical sulfur insertion reactions may be a distinct subgroup within the burgeoning Radical SAM superfamily. This article is part of a Special Issue entitled: Radical SAM enzymes and Radical Enzymology.

S-adenosylmethionine and radical-based catalysis

S-adenosylmethionine is the major methyl donor in all living organisms, but it is also involved in many other reactions occurring through radical-based catalysis. The structure and function of some of these enzymes, including those involved in the synthesis of the molybdenum cofactors, biotin, lipoate, will be discussed.

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.

Transfer of sulfur to biotin from biotin synthase (BioB protein)

In biotin synthase reactions carried out in vitro, we observed efficient transfer of 35S to biotin from partially purified E. coli biotin synthase (product of the bioB gene) labelled by biosynthetic incorporation of [35S]-cysteine. Mass spectrometry was consistent with covalent alteration of the protein in the assay. These results suggest that BioB protein is a reagent, not a catalyst.

Biotin synthase from Escherichia coli: isolation of an enzyme-generated intermediate and stoichiometry of S-adenosylmethionine use

A cell-free extract from Escherichia coli containing an E. coli biotin synthase that was expressed to approx. 1% of soluble cell protein by cloning the E. coli bioB gene was used to investigate the biotin synthase reaction. The pH optimum was between 8 and 8.5, and the reaction velocity was dependent on the concentrations of dethiobiotin, cysteine, S-adenosylmethionine and asparagine. The catalytic-centre activity of the enzyme in vitro was estimated to be 0.95 h-1, and each molecule of enzyme turned over less than one molecule of dethiobiotin, i.e. the enzyme was not acting catalytically. HPLC analysis of reaction mixtures revealed the presence of a compound with the characteristics of an intermediate: (1) it was labelled with 14C, and therefore derived from the [14C]dethiobiotin substrate; (2) it was present only in reaction mixtures containing biotin synthase; (3) it was not derived from [14C]biotin; (4) 35S from [35S]cystine was incorporated into the intermediate during the reaction; (5) its synthesis was dependent on the presence of S-adenosylmethionine, and was decreased when free cysteine was omitted from the reaction; (6) it could be isolated from the reaction mixture by chromatography and then re-introduced into an assay as the substrate, whereupon it was converted to biotin; (7) this conversion to biotin was S-adenosylmethionine-dependent. During the reaction S-adenosylmethionine was cleaved to methionine and presumably 5'-deoxyadenosine. Observation of the intermediate allowed us to perform experiments to determine the stoichiometry of S-adenosylmethionine use. We propose that two molecules of S-adenosylmethionine are used to synthesize one molecule of biotin, i.e. one from dethiobiotin to the intermediate, and a second from the intermediate to biotin.

Biotin synthase from Escherichia coli, an investigation of the low molecular weight and protein components required for activity in vitro

We have developed a radiochemical method for the measurement of biotin synthase activity in vitro. A cell-free extract from an Escherichia coli strain containing a cloned bioB (biotin synthase) gene was incubated with [14C]dethiobiotin, which was converted to [14C] biotin. The assay was used to identify the low molecular weight compounds and two of the proteins that, in addition to the bioB gene product, are required for biotin synthase activity in vitro. The low molecular weight compounds are cysteine; S-adenosylmethionine; thiamine pyrophosphate; Fe2+; a pyridine nucleotide (the most effective being NADPH); and one of the amino acids asparagine, aspartate, glutamine, or serine. The proteins ae flavodoxin and ferredoxin (flavodoxin)-NADP+ reductase (EC 1.18.1.2). A third thiamine pyrophosphate-dependent protein is also required for activity. When the cell-free extract was incubated with nonlabeled dethiobiotin and either [35S]cysteine or [35S]cystine, 35S was incorporated into biotin, and we present further evidence that cysteine, and not S-adenosylmethionine or methionine, is the sulfur donor for the biotin synthase reaction.

Improvement of a d-biotin-hyperproducing recombinant strain of Serratia marcescens

We previously reported that a recombinant strain, SB412(pLGM304), was constructed from acidomycin-resistant mutants of Serratia marcescens and produced 200 mg of d-biotin per liter of a medium containing sucrose and urea (Sakurai et al., 1993a, b). In the present work, we intended to improve the d-biotin production. Both ethionine and S-2-aminoethylcysteine resistances were added to the host strain SB412, producing d-biotin at 20 mg l-1, and a resultant strain, ETA23, producing it at 33 mg l-1, was obtained. Cells of ETA23 did not maintain pLGM304 stably after greater than 30 generations under non-selective culture conditions. A new recombinant plasmid, pLGM304P, was constructed so as to be composed of pLGM304 and the parB locus, a plasmid-stabilizing element. ETA23 stably maintained pLGM304P after 50 generations under non-selective culture conditions. ETA23(pLGM304) produced 250 mg l-1 of d-biotin in a shaking flask under batch culture conditions and 500 mg l-1 in a jar fermentor under fed-batch culture conditions.

Biosynthesis of biotin from dethiobiotin by the biotin auxotroph Lactobacillus plantarum

Lactobacillus plantarum requires biotin for growth. We show that in the presence of high levels of the biotin biosynthetic precursor, dethiobiotin, L. plantarum synthesizes biotin and grows in medium with dethiobiotin but without biotin. Lactobacillus casei also grew under similar conditions.

Molecular breeding of a biotin-hyperproducing Serratia marcescens strain

We previously reported that an acidomycin-resistant mutant of Serratia marcescens Sr41, SB304, and a mutant that was derived from SB304 and was resistant to a higher concentration of acidomycin, SB412, produced 5 and 20 mg of D-biotin, respectively, per liter of a medium containing sucrose and urea (N. Sakurai, Y. Imai, M. Masuda, S. Komatsubara, and T. Tosa, Appl. Environ. Microbiol. 59:2857-2863, 1993). In order to increase the productivity of D-biotin, the biotin (bio) operons were cloned from strains SB412, SB304, and 8000 (wild-type strain), and pLGM412, pLGM304, and pLGW101, respectively, were obtained through subcloning. These plasmids harbored 7.2-kb DNA fragments coding for the bioABFCD genes on a low-copy-number vector and were introduced into SB304, SB412, and 8000. Among the resulting recombinant strains, SB412(pLGM304) exhibited the highest D-biotin production (200 mg/liter) in the production medium. The plasmid was stably maintained in cells. Unexpectedly, SB412(pLGM412) grew very slowly, and the D-biotin productivity of this recombinant strain was not evaluated because pLGM412 was unstable.

Construction of a Biotin-Overproducing Strain of Serratia marcescens

We have isolated mutants resistant to acidomycin, a biotin analog, from Serratia marcescens Sr41. Strain SB304, resistant to 0.5 mg of acidomycin (frequently called actithiazic acid) per ml, produced 5 mg of d -biotin per liter of a medium containing sucrose and urea. Strain SB412, which was isolated from SB304 on a minimal agar plate containing 2 mg of acidomycin per ml and 0.1 mg of 5-(2-thienyl)-valeric acid per ml, produced 20 mg of d -biotin per ml. The two enzymes related to biotin synthesis were found to be released from biotin-mediated feedback repression in these mutants. Transductional analysis revealed that SB412 had acquired at least two mutations, one in the biotin operon locus and the other in an unknown locus distant from the biotin operon locus.

Assay for biotin in the presence of dethiobiotin with Lactobacillus plantarum

At concentrations greater than approximately 0.5 microM, dethiobiotin can cause the bioassay for biotin, which employs Lactobacillus plantarum, to over value the actual biotin level. This can be as much as 30-fold at 10 microM DL-dethiobiotin and 5 pM biotin. Dethiobiotin does this by exerting a sparing effect on the biotin response by the assay organism. We demonstrate one way to determine the actual biotin concentration in the presence of interfering levels of dethiobiotin.

Determination of the metabolic origin of the sulfur atom in thiamin of Escherichia coli by mass spectrometry

In this study cells were grown in 34S-sulfate or L-[sulfane-34S]thiocystine, and the effects of unlabeled methionine and cystine on incorporation of sulfur into methionine, cystine and thiamin were determined. Unlabeled methionine effectively suppresses the incorporation of 34S into methionine but not into cysteine or thiamin. In contrast, cystine blocks incorporation of 34S only to approximately the relative ratio of 32S to 34S indicating, that cysteine is closely related to the origin of the sulfur in thiamin, and therefore the sulfane sulfur of thiocystine is also an effective source of the thiamin sulfur.

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.